KR20120114459A - Method for analyzing drawing file to estimate the amount of material for reinforced concrete frame construction - Google Patents

Abstract

PURPOSE: A drawing file analyzing method for calculating the number of construction materials for a ferroconcrete framework is provided to supply a structure quantity calculation result by automatically calculating the quantity and types of structures based on various symbols in a design drawing. CONSTITUTION: A structure drawing and a list drawing are distinguished and recognized by analyzing texts in a design drawing(S130). A list table of each structure including the types, extent, or thickness of structures is generated by analyzing the texts in the list drawing(S140). The number of the structures is calculated by analyzing the texts in the structure drawing(S150). A rebar type of each unit area of individual unit structures and the number of reinforcing bars are calculated by analyzing points and lines in the list drawing(S170). A kind of the whole of the individual unit structures and the total number of the reinforcing bars are calculated by matching the rebar type and interval information with the size of the individual unit structures(S180). [Reference numerals] (S100) Inputting a drawing file; (S110) Converting the drawing file into a standard form; (S120) Inputting an imaginary area determining signal; (S130) Recognizing the drawing of a structure and a table in a design drawing; (S140) Generating a structure list table; (S150) Calculating the number of structures; (S160) The kind and number of rebars per unit area of an individual unit structure; (S170) Calculating the kind and total number of rebars of an individual unit structure; (S180) Calculating the total length of rebars; (S190) Calculating the quantity of concrete and forms; (S200) Highlighting omitted portions; (S210) Display a structure drawing and a structure list table; (S220) Adding or deleting a structure list and inputting a construction area determining signal; (S230) Re-calculating the total length of rebars and the quantity of concrete and forms

Description

METHOD FOR ANALYZING DRAWING FILE TO ESTIMATE THE AMOUNT OF MATERIAL FOR REINFORCED CONCRETE FRAME CONSTRUCTION}

The present invention relates to a drawing file analysis method for calculating the quantity of reinforced concrete frame construction materials, and in particular, points, lines, faces, and texts indicated in the drawing file input regardless of the format of the drawing file without constructing a separate drawing database. Automatically analyze the symbols such as and automatically extract the structure and type of reinforcing bar, automatically calculate the dimension information of the structure and reinforcing bar, and based on the calculated dimension information, the total length of the reinforcing bar and the concrete and formwork The present invention relates to a drawing file analysis method for calculating the quantity of reinforced concrete frame construction materials to automatically calculate the total quantity of steel.

In general, as a method for calculating the number of reinforced concrete and frame construction work from the architectural design drawing, a method of visually checking the design drawing by the human eye and calculating a list and the quantity of structures required for the frame construction is used. That is, a person directly views drawings of the structure, and inputs detailed information of the structure such as the length, perimeter, and volume of the structure from the elevation, floor plan, and cross-sectional view, and then reinforces the concrete, The quantity of formwork is calculated by simple multiplication and addition. Among these, simple multiplication and summation time takes less than 5% of the total construction quantity calculation process.

Here, the structures required for the construction of reinforced concrete and steel structures, etc. are very diverse according to the cross-sectional area, reinforcement method, etc., the drawing methods vary depending on the type of construction, according to the type of construction shown on the elevation, floor plan, cross-sectional view The location of the symbol is also very complicated.

However, the method of calculating the quantity of a structure such as reinforced concrete by directly checking the design with the naked eye takes a long time, and due to a mistake, the structure list or number is missing or an error occurs in calculating the location information of the structure. The disadvantage is that the quantity calculation accuracy is poor.

Recently, a method of automatically calculating the quantity of a structure from a design drawing has been proposed to solve the above-mentioned drawbacks. However, in the database, construction area information corresponding to the design drawing and structure information corresponding to the construction area information are separately constructed. When a user requests a quotation by a specific construction, the user extracts information about the construction from a database and calculates a quotation required for the construction.

Therefore, this method has a disadvantage in that it is difficult to calculate the quantity of the structure using design drawings not built in the database.

An object of the present invention to solve the shortcomings of the background technology is to extract the associated keywords through the text analysis of the input design drawings to distinguish the structure drawings and schedule drawings, and to analyze the points, lines and text of the schedule drawings Generate the list table, analyze the structure drawing to calculate the number of unit structures by type and dimension, and analyze the list drawing to calculate the number of reinforcing bar type and size per unit area of the individual unit structure. In accordance with the present invention, a drawing file analysis method for calculating the quantity of reinforced concrete frame construction materials for automatically calculating the total number of reinforcing bars is provided.

In addition, the present invention automatically calculates the quantity of reinforced concrete frame construction material that can automatically calculate the amount of concrete and formwork by automatically calculating the volume and perimeter area of the unit structure by automatically extracting the dimensional information of the unit structure from the structure drawing To provide a drawing file analysis method for.

In addition, the present invention is a drawing for calculating the quantity of reinforced concrete frame construction material to be able to identify the points, lines, faces and text by converting the design drawings of different file formats into standard file formats that can be analyzed in the system Provides a file analysis method.

Drawing file analysis method for calculating the quantity of reinforced concrete frame construction materials of the present invention for solving the problem is the step of receiving at least one design drawing file, and analyzing the text in the input design drawings to distinguish the structure drawings and schedule drawings And generating a list table for each structure including the type of the structure, the area of the structure or the thickness of the structure, and the type and spacing of each reinforcing bar by analyzing the text of the list drawing, and analyzing the text in the structure drawing. Calculating the number of pieces by dimensions, analyzing points and lines in the schedule drawings for each unit structure, and calculating the number of reinforcing bars per unit area and the number of lengths of the individual unit structures, and for each of the unit structures. When reinforcing bar type and spacing information of star list table correspond to dimension of unit structure Computing the total number of reinforcing bars by type and length for the entire unit structure, Calculating the total length of reinforcing bars by type by adding up the total number of reinforcing bars by type and length for each unit structure The volume and perimeter of each structure are calculated using the area or thickness of each structure and the dimensions of each structure, and the volume of concrete and formwork are calculated by summing the volume and area of each structure by the number of structures.

Here, the structure drawing and the schedule drawing recognition may be recognized by extracting an associated keyword from the text displayed in the corresponding area, and may further include converting the design drawing file input before the structure list generating step into a standard file format. .

The method may further include visually displaying the analyzed structure drawing and the generated structure list table before calculating the number of reinforcing bars by type and length. The displaying may include highlighting missing portions not reflected when generating the structure list table. It may further include.

The display may further include adding or deleting the input list to the structure list table by receiving an addition or deletion signal of the construction area and the structure list from the user, and recalculating the number of structures by dimensions.

Further, before calculating the dimensions of the structure, points, lines, and text in the structure drawing are analyzed to generate a dimension list, and the dimension of the structure is selected as the dimension of the object closest to the corresponding structure on the dimension list.

In addition, the process of generating the column and beam list of the structure in the structure list generation step extracts all the line components of the corresponding area, determines whether or not the intersection with the outermost line for each line, the line not connected to the outermost line After removing the components, the text can be analyzed to create a structural inventory.

In addition, the process of generating the slab list of the structure in the step of generating the structure list table extracts all the line components of the corresponding area and determines whether the outermost lines intersect with each other to remove the line components not connected to the outermost lines. Generating a structure list table by analyzing text, and generating a reinforcing bar list by analyzing each line component of a shape region consisting of line components not connected to the outermost line, but generating a reinforcing bar list, requires that the line components in the shape region have the same axis. In the case where the length is the longest and the straight line is determined as the upper root, the line component in the shape region is determined to be the lower root when the attribute information of the line in which the straight line shorter than the upper root is continuously arranged or recognized in the longitudinal direction is a dotted line, The line component in the shape region consists of a straight line shorter than the upper root and is in the longitudinal direction. If it is not continuously arranged in contact with each other, it is determined as the upper end of the end, and when the line component in the shape region is shorter than the upper end and some parts are bent, it is determined to be the bending root.

In addition, the structure list generation step may further include generating a list of additional structures such as retaining walls or stairs, and generating the retaining wall or stairs structure list may include extracting points, lines, and text objects in the drawing, and connecting the respective line components. Analyzing the text object to determine the type of the line, calculating the dimension from the length of the line, adding it to the list, and determining whether a point component exists in each line component. Analyzing the text object connected to to determine the type of reinforcement pointed to by the point, calculating the number of reinforcing bars by matching the placement interval of the point to the length of the line component at which the point is located, and the point of the extracted object Or analyzing the text component not connected to the line component to calculate the thickness of the structure. .

The present invention is limited to the design drawings that can be analyzed by analyzing the various symbols, such as points, lines, and text in the design drawings, automatically calculates the type and quantity of structures in real time when one or more design drawing files are input. It does not provide the user with the result of calculating the quantity of the structure to a variety of users, there is an advantage that can prevent the time spent and manpower waste of calculating the quantity of the structure.

In addition, by automatically calculating the quantity of the structure without building a separate database, there is an advantage that can reduce the time and cost for building the database.

In addition, the present invention converts the design drawings of different file formats into standard file formats that can be analyzed in the system and recognizes symbols such as text in the drawings, thereby providing high compatibility with design drawings of various file formats. There is this.

1 is a block diagram of a structure quantity calculation system through the analysis of the drawing file according to an embodiment of the present invention.
2 illustrates an example of a screen displayed through the display device of FIG. 1.
3 is a sequential flowchart of a drawing file analysis method for calculating the amount of reinforced concrete frame construction material according to an embodiment of the present invention.
Figure 4 is an exemplary view of a table diagram analyzed in accordance with an embodiment of the present invention.
5 to 7 are exemplary views of the structure diagram analyzed in the embodiment of the present invention.
8 to 10 is a view illustrating a structure list table according to an embodiment of the present invention.
11 is an exemplary view of the dimension list in accordance with an embodiment of the present invention.
12 is an exemplary view of the final product produced by the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

FIG. 1 is a diagram illustrating a structure quantity calculation system configuration through analysis of a drawing file according to an exemplary embodiment of the present invention, and FIG. 2 is an exemplary view of a screen displayed through the display device of FIG. 1. And a display device 300.

Here, the quantity calculation system 100 analyzes the text from one or more input design drawing files to distinguish the structure drawings from the schedule drawings, and analyzes the text in the schedule drawings and the point and line components to generate the structure list table. Here, the structure list includes the type of structure, the area or thickness of the structure, the diameter and spacing of the rebar.

In addition, the quantity calculation system 100 analyzes symbols such as points, lines, and texts in the structure drawing to calculate the number of structures by each dimension, and calculates the number of rebar types and lengths per unit area of the individual unit structure, and then the unit. Calculate the total number of rebars by type and length for the entire structure, and calculate the total weight of rebars by type by multiplying the unit specific gravity per length by type.

In addition, the quantity calculation system 100 calculates the volume and the perimeter of each structure by using the area or thickness of each structure on the structure list table, and the dimensions of each structure, and adds the volume and area of each structure by the number of structures. Calculate the amount of concrete and formwork.

The input device 200 includes a mouse 220 that receives a user input signal for designating, adding or deleting an area to be analyzed on a design drawing, and a keyboard 210 that receives a text input signal for adding a structure type. .

The display device 300 includes a design drawing display unit 310, a structure list table display unit 320, and an additional information input unit 330.

Here, the design drawing display unit 310 displays the design drawing analyzed by the quantity calculation system 100 so that the user can designate the position of the structure list in the schedule drawing or the structure position on the elevation, sectional view, and plan view by using the mouse 220. Allow, add, or delete. In addition, the design drawing display unit 310 displays a design drawing highlighting a portion that is missing or unclear and analyzed when generating the structure list table, so that the user can easily identify the missing or unclear portion.

The structure list display unit 320 displays a structure list table generated through text or point and line analysis in the quantity calculation system 100, and displays a calculation result when the structure quantity calculation is completed.

The additional information input unit 330 allows the user to input information such as additional structure type or rebar type.

Figure 3 is a sequential flowchart of a drawing file analysis method for calculating the amount of reinforced concrete frame construction material according to an embodiment of the present invention, Figure 4 is a diagram illustrating a table analysis according to an embodiment of the present invention, Figures 5 to Figure 7 is an exemplary view showing a structure diagram analyzed in an embodiment of the present invention, FIGS. 8 to 10 are exemplary view of a structure list table according to an embodiment of the present invention, and FIG. 11 is an exemplary view of a dimension list table according to an embodiment of the present invention.

1 to 11, first of all, the present invention receives one or more design drawing files (S100). In this case, the design drawing file may be various file formats such as DWG, DXF, or BMP capable of identifying symbols such as text and dimensions indicated in the drawing. In addition, when the input design drawing file is not a preset standard file format, the corresponding design drawing file is converted into a standard format that can be analyzed by the quantity calculation system 100 (S110). Here, the standard file format may include a drawing eXchange Format (DXF) and an eXtensible Markup Language (XML) format. If the input design drawing is a standard file format, the file conversion step of step S110 may be omitted.

Subsequently, the inputted design drawing is displayed on the design drawing display unit 310 so that a user can visually check the design drawing. Then, the user visually checks the design drawing displayed on the design drawing display unit 310, and mouses on the table drawing (see FIG. 4) and the structure drawing (see FIGS. 5, 6, and 7) of the part where the quantity of the structure is desired. Drag to 220 to specify (S120).

Here, although the embodiment of the present invention has been described as a user designating a structure drawing and a table drawing for calculating the quantity of the structure, omitting step S120 designated by the user, and searching the positions of the codes 801 and 901 by keywords. Thus, all the drawings in the input design drawing file can be automatically recognized and analyzed.

Next, texts in all the drawings designated or input by the user are analyzed to distinguish the structure drawings and the schedule drawings (S130). In general, the names of the types of drawings are indicated in the structure drawings and the schedule drawings. For example, names such as' plan view ',' section view ', and' elevation view 'are shown in the structure drawing, and' CON'C COLUMN LIST ',' CON'C GIRDER & BEAM LIST ', and' CON'C SLAB. Since a name such as 'LIST' is displayed, an associated keyword is extracted from the text written in each drawing to recognize the type of the drawing. For example, texts such as 'COLUMN', 'GIRDER & BEAM', and 'SLAB' are set as related keywords in a schedule drawing, and when the analyzed keyword is one of the keywords, the corresponding figure is recognized as a schedule drawing.

Meanwhile, when the structure drawings and the schedule drawings are distinguished and recognized, each of the points, lines, and texts shown in the schedule drawings of FIG. 4 is analyzed to generate a structure list table as illustrated in FIGS. 8 to 10 (S140).

8 is an exemplary view illustrating a column list table, and a process of generating a column and a beam list table will be described with reference to FIG. 4.

First, all line components of all regions in the structure diagram of FIG. 4 are extracted, and it is determined whether or not the intersection with the outermost line A is performed for each line. At this time, since the line components constituting the form of the column or beam do not intersect the outermost line (A), the corresponding line component is judged to be a line representing the form of the column or beam, and all of them are removed. Create a list of structures for the structure. At this time, it is determined that the text located on the outside of the surface formed by the outermost line (A) is the name of the structure, and the text located inside the surface formed by the outermost line (A) is the dimension information of the structure. And it is determined that the type of reinforcing bar occupying the unit area of the structure, it is reflected in each list.

Referring to FIG. 8, items such as a symbol 801, a layer 802, an area 803, a height 804, a reinforcing bar name 806, a reinforcing bar type 807, and a corresponding item list are generated. At this time, the type of reinforcement (807) is shown in the form such as 8-HD22 or HD10 @ 300, in the 8-HD22 '8' is the number of reinforcing bars 'HD22' means the type of reinforcing bars, HD10 @ 300 in 'HD10' Is the type of reinforcing bars, and '300' refers to the spacing of the corresponding bars of the rebar.

Here, the height 804 corresponds to the height of the structure that is obtained in the process of calculating the number of unit structures to be described later by size (S150), that is, the height of each floor, and the number of unit structures 805 is determined by the number of unit structures by height. Correspondingly, the length 808 and the number of rebars per unit area 809 correspond to the length and number of structures obtained in the process of calculating the type of rebars per unit area and the number of rebars per length of the unit structure, which will be described later, and the total number of rebars 810. Corresponds to the total number of reinforcing bars calculated by matching the reinforcing bar type and spacing information with the height 804 of the column, and the total length 811 corresponds to the total number of reinforcing bars calculated by corresponding the length of the reinforcing bar 808. Corresponds to the total length.

FIG. 9 is an exemplary view of a beam list table. The beam list table of FIG. 9 is generated in the same manner as the above-described column list table generating process, and the remaining columns except for the length 903 and the position 907 of each item on the list table are the columns of FIG. 8. Same as the item on the list. Here, the length 903 indicates the cross-sectional length of the area where the beam is installed on the plan view, and the position 907 indicates the position where the reinforcing bar is disposed.

10 is an exemplary view of the slab list table, the slab list table should be performed with the analysis of the lines belonging to the shape of the structure as well as text analysis. Here, the method of generating the slab list table through text analysis is the same as the above-described method of generating the column and beam list table, and thus a detailed description thereof will be omitted.

Referring to FIG. 4, the slab list table generation process is performed to generate a rebar list by analyzing each line component of the shape region including line components not connected to the outermost line.

More specifically, first, the lengths of all the line components in the shape region are extracted, and the longest and straightest 'X4, Y4' on the same axis is determined as the upper root. In the case of X3, X5, Y3, and Y5 'whose line components in the shape region are dotted lines, it is determined as the lower root. At this time. If the file format is an image file such as BMP, it can be determined by the dotted line that the straight lines shorter than the upper root (X4) are adjacently arranged in the longitudinal direction, and in the case of CAD files such as DWG and DXF, the property information of each line type Therefore, referring to the attribute information of the corresponding line, it is possible to determine whether the corresponding line is a dotted line.

In addition, in the case of 'X1, Y1' where the line component in the shape region is made of a straight line shorter than the upper roots X4 and Y4, and is not continuously disposed adjacent in the longitudinal direction, it is determined as the end upper root, and the line component in the shape region is determined. 'X2, Y2' is shorter than the upper root and partially bent.

In addition, the list generation of the retaining wall or the staircase structure is performed in a manner different from that described above. For example, to generate a list of the staircase structures shown in FIG. 7, first, points, lines, and text objects in the drawing are extracted. The text object connected to the line component is analyzed and the line type and spacing information are added to the list. In addition, if a point component exists in each line component, the text object connected to the point component is analyzed, and the type and spacing information of the bar indicated by the point are extracted and added to the list.

At this time, the specific object in the additional structure drawings, such as retaining wall or stairs may not be automatically recognized correctly by the system, highlight the incorrect object and then create a list by user input.

Meanwhile, when generation of the structure list table is completed, the number of structures is calculated for each dimension by analyzing the text in the top view shown in FIG. 5 and the cross-sectional view shown in FIG. 6 (S150). In this case, in order to calculate the dimensions of each structure, points, lines, and texts in the structure drawing are analyzed and a dimension list table is generated in advance as shown in FIG. 11, and the dimensions of the corresponding structure are calculated by referring to the dimension list table. In FIG. 11, the dimension item corresponds to a reference numeral arbitrarily assigned. Thus, when the dimension item is generated, the dimension list table is generated by calculating the actual length corresponding to the length of the text or the text representing the dimension in the structure drawing.

After that, the number of unit structures is calculated for each dimension by referring to the dimension list table. For example, in FIG. 5, three symbols 'C1' representing pillars are present, and two 'C2' are present. 6, the height of each layer is 2,500. Accordingly, the height item 804 of FIG. 8 is filled with the height 2,500 of the corresponding floor, and the number item 805 of the unit structure is filled with the number '3' of C1 and the number '2' of C2.

In addition, in FIG. 5, three symbols 'nG1' representing beams are present and three 'nB1' are present. At this time, since two 'nG1' is located in an area having a cross section length of 7,000 and one 'nG1' is located in an area having a cross section length of 8,000, the number of the same symbols 'nG1' must be calculated for each dimension.

Here, the dimension of each structure is selected as the dimension of the object closest to the structure on the dimension list table. For example, the object closest to the first nG1 (B1) would be 'L1' and the dimension of that object would be 7,000, so choose the dimension of nG1 (B1) as 7,000 and closest to the second nG1 (B2). The object becomes 'L2' and the dimension of the object corresponds to 8,000, so the dimension of nG2 (B2) is selected as 8,000. Here, when the planes (a, a ') representing the columns are located at both ends of the lines (L1, L1) corresponding to nG1 (B1) or nG2 (B2), the dimension can be calculated accurately using only the line components in the drawing. In this case, the length from the center of the plane (a, a ') in contact with both ends of each line (L1, L2) should be selected as the actual length of the line.

In this way, the number of unit structures in the structure drawing is calculated for each dimension.

In addition, a structure such as a retaining wall or a staircase calculates the number of rebars by type and length through a method different from the above-described method. Referring to FIG. 7, when the text 401 is connected to a line component as shown by reference numeral 405, the type of the line is determined through text analysis, and the length of the reinforcing bar is analyzed by analyzing the length of the line on the drawing. Determine. In addition, it is determined whether a point component exists in each line component, and if a point component exists in each line component, the text object 401 connected to the corresponding point component is analyzed to determine the type of reinforcement indicated by the corresponding point component. The number of reinforcing bars is calculated by making the arrangement interval of the point correspond to the length of the line component in which the point is located.

Subsequently, points and lines in the schedule drawing are analyzed for each unit structure to calculate the type and length of reinforcing bars per unit area of the individual unit structures (S160). For example, since there are eight main roots represented as points in the column C1 of FIG. 5, 8 is filled in the number of bars (809) per unit area of the column list table of FIG. 8, and 1,800 ( 400 + 400 + 500 + 500) Since there is one size, 1 is filled in each item of the number of rebars per unit area (809). Since one size exists, 1 is filled in each item of the number of bars 809 per unit area.

In the same way, the number and length of each reinforcing bar are calculated from the beam shape and the slab shape.

Subsequently, when the type and length of the reinforcing bars per unit area of the individual unit structures are calculated, the type and length of the reinforcing bars for the entire unit structure are calculated (170). For example, since the main roots constituting the pillar C1 are vertically disposed and are not added according to the spacing, eight main roots are required in the entire structure C1. The multiplied value 24 is filled in the total number of heads 810 items. In addition, since the type of reinforcement is HD10 @ 300, which means that HD10 reinforcing bars are arranged in units of 300 cm, the size of 8 can be obtained by dividing the height of 2500 cm by units of 300 cm. Accordingly, the total number item 810 of the root canal is filled with 24, which is a value obtained by multiplying the number 805 3 of C1 by the number 1 of the 1,800 cm root mass per unit area and the batch number 8 of the root mass for height.

In this way, the total number of rebars by type and length is calculated for the entire structure of each column, beam and slab.

Then, the total length of the rebars by type is calculated using the calculated total number of rebars by type and length (S180). For example, since C1 has a length of 2,500 per head and a total number of heads of 24, a dimension of 24X2,500 = 60,000 can be obtained. Therefore, the total length is calculated in the same manner for the remaining bars.

Subsequently, the volume and the perimeter of each structure are calculated using the area or thickness of each structure and the dimensions of the structure, and the volume of concrete and the form of concrete are calculated by summing the volume and area of each structure by the number of structures (S190). ). For example, the area of C1 is 400 × 500 and the height is 2,500, so the volume of C1 is 500,000,000 cm 3, so the amount of concrete is required 500,000,000 cm 3. Therefore, after calculating the volumes for all the unit structures in this manner and adding them together, it is possible to calculate the total amount of concrete required for construction. Since the area around C1 is 2X400X2,500 = 2,000,000cm2, and the left and right area is 2X500X2,500 = 2,500,000cm2, the total circumference area of C1 is 2,000,000cm2 + 2,500,000cm2 = 4,500,000cm2. , The amount of formwork of C1 is 4,500,000cm2. Therefore, after calculating the volume of all the unit structures in this manner and sum them all, it is possible to calculate the total quantity of formwork required for the construction.

In addition, in the case of the staircase illustrated in FIG. 7, a text quantity which is not connected to a point or line component among the extracted objects may be analyzed to calculate the thickness of the structure, and then the concrete quantity may be calculated using the same.

On the other hand, when the calculation of the total length of the rebar and the amount of concrete and formwork is completed, the result is displayed on the structure list table display unit 320, and the analyzed structure drawing is displayed on the design drawing display unit 310 (S210). In addition, the present invention additionally highlights the missing portion or the portion that is not reflected when calculating the amount of concrete and formwork, or the symbol is not analyzed because the symbol is not clear, so that the user can check the missing or reflected portion in real time. You can do that.

Subsequently, the user inputs an addition or deletion signal or a structure type of the object corresponding to the structure by using the input device 200 (S220). In other words, after the user visually checks the design drawing display unit 310, the user may add or delete an object corresponding to the structure by dragging or clicking a specific position of the design drawing display unit 310 with the mouse 220.

In addition, if a user is missing from the structure list table or there is a structure to be deleted, the user drags or clicks the structure type in the schedule drawing or inputs the corresponding information to the additional information input unit 330 by using the keyboard 220. Information added or deleted in the process can be reflected in the structure list table.

Subsequently, the quantity calculation system 100 recalculates the total length of the rebar and the amount of concrete and formwork by reflecting the data added or deleted by the user.

12 is a final result example table calculated by the present invention, it is possible to obtain the total amount of concrete and the total weight and formwork for the total length of the reinforcement, calculated through the above-described process, and input the unit price in the result obtained You can easily calculate the cost.

In the exemplary embodiment of the present invention, a specific part of the drawing is missing or unclear in the quantity calculation system, or it is described as being able to designate the location of the structure or add the type of the structure by the user's selection. For example, steps S200 to S230 may be omitted.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the appended claims are intended to cover such modifications or changes as fall within the scope of the invention.

100: quantity calculation system
200: input device
210: keyboard
220: mouse
300: display device

Claims (10)

Receiving at least one design drawing file;
Analyzing the text in the input design drawing and recognizing the structure drawing and the schedule drawing;
Analyzing the text of the list of drawings to generate a list of structures for each structure including the type of structure, the area of the structure or the thickness of the structure, and the type and spacing information of each reinforcing bar;
Analyzing the text in the structure drawing to calculate the number of structures for each dimension;
Calculating the number of rebar types and lengths per unit area of each unit structure by analyzing points and lines in the schedule drawings for each unit structure;
Calculating the total number of reinforcing bars for each type and length of the entire unit structure by matching the type of reinforcing bar and the spacing information of the list of structures of each structure with respect to the dimension of the unit structure for each unit structure;
Calculating the total length of reinforcing bars by type by summing the total number of bars by type and length calculated for each unit structure; And
Calculate the volume and circumference of each structure using the area or thickness of each structure on the list of structures and the dimensions of the structure, and calculate the concrete and formwork by adding the volume and area of each structure by the number of structures. Drawing file analysis method for calculating the amount of reinforced concrete frame construction materials, characterized in that.
The method of claim 1,
Recognizing the structure drawings and schedule drawings is a drawing file analysis method for calculating the quantity of reinforced concrete frame construction material, characterized in that to extract the associated keywords from the text displayed in the corresponding area.
The method of claim 1,
And converting a design drawing file input before the structure list table generation step into a standard file format.
The method of claim 1,
The method for analyzing the drawing file for calculating the number of reinforced concrete frame construction material further comprising the step of visually displaying the structure drawings and the generated structure list table analyzed before the number of rebar type and length.
The method of claim 4, wherein
The display step,
Drawing file analysis method for calculating the amount of reinforced concrete frame construction material, characterized in that it further comprises the step of highlighting the missing portion not reflected when generating the structure list table.
6. The method of claim 5,
Reinforcing bars further comprising the step of adding or deleting the input list to the structure list table by receiving the addition or deletion signal of the construction area and the structure list from the user after the display step, and recalculating the number of structures by dimensions A drawing file analysis method for calculating the quantity of concrete frame construction materials.
The method of claim 1,
Before calculating the dimension of the structure, the point, line and text in the structure drawing is analyzed to generate a dimension list table, and the dimension of the structure is selected as the dimension of the object closest to the corresponding structure on the dimension list table A drawing file analysis method for calculating the quantity of reinforced concrete frame materials.
The method of claim 1,
The process of generating a column and beam list of the structure in the structure list generation step,
Reinforced concrete characterized by extracting all the line components of the corresponding area, determining whether each line intersects the outermost line, removing the line components not connected to the outermost line, and analyzing the text to create a structure list table Drawing file analysis method for calculating the quantity of framing construction materials.
The method of claim 1,
The process of generating a slab list of the structure in the structure list generation step,
Extracting all line components of the corresponding area, determining whether each line intersects the outermost line, removing line components not connected to the outermost line, and analyzing the text to generate a structure list table;
The rebar list is generated by analyzing each line component of the shape region including line components not connected to the outermost line, but generating rebar list.
If the line component in the shape region is the longest and straightest in the same axis, it is determined as the upper root,
If the line component in the shape region is continuously disposed adjacent to the upper root shortly in the longitudinal direction, or the attribute information of the recognized line is the dotted line, it is determined as the lower root,
If the line component in the shape region is made of a straight line shorter than the upper root, and is not continuously disposed adjacent in the longitudinal direction, it is determined as the upper root of the end,
Drawing file analysis method for calculating the amount of reinforced concrete frame construction material, characterized in that it is determined that the line component in the shape region is shorter than the upper bar and part is bent connected.
The method of claim 1,
The structure list generation step further includes a process of generating a list of retaining walls or stairs structures,
To create a retaining wall or stair list,
Extracting points, lines, and text objects in the drawing;
Analyzing the text object connected to each line component to determine the type of the line, calculating the dimension from the length of the line, and adding it to the list;
Determines whether a point component exists within each line component, and if a point component exists within each line component, analyzes the text object connected to the point component to determine the type of reinforcing bar indicated by the point component, and determines the placement interval of the point. Calculating the number of reinforcing bars in correspondence with the length of the line component;
And calculating a thickness of the structure by analyzing text components not connected to a point or line component among the extracted objects.

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