KR20220056681A - Auto design program of a breast wall - Google Patents

Abstract

An automation program for designing a three-dimensional breast wall according to the present invention comprises: an initial input step (S100) of inputting a business name and initial data of a construction site; a site setting step (S200) of dividing an application site of a breast wall structure (A); a cross-section setting step (S300) of setting a cross-section of the breast wall structure (A); an installation shape designating step (S400) of designating a longitudinal installation shape of the breast wall structure (A) by a point or a line; a three-dimensional modeling step (S500) of applying the cross-section of the breast wall structure (A) designated as the cross-section setting step (S300) to a position set in the installation shape designating step (S400); and a start-end point designating step (S600) of designating a start point (A1) and an end point (A2) of the breast wall structure. The cross-section setting step (S300) is a step of determining a geometrical shape of the breast wall structure (A), and includes selecting any one data from the breast wall shape data (D100) for storing the shape of the breast wall structure including a gravity-type breast wall, a semi-gravity-type breast wall, an L-type breast wall, an inverse T-type breast wall, and a subwall-type breast wall. In this case, the breast wall shape data (D100) is stored in a breast wall data library (L), and the geometric shapes and sections of the breast wall shape data (D100) are sections that are designed according to design conditions of the breast wall structure (A) and examined for stability of a ground bearing force, stability of activity, stability of conductivity, and stability of a slope including the breast wall, thereby determining the geometric shapes and sizes from the design and examination. According to the present invention, it is possible to quickly and accurately perform a drawing operation and a quantity calculation operation.

Description

3D retaining wall design automation program {AUTO DESIGN PROGRAM OF A BREAST WALL}

The present invention relates to the field of construction, and more particularly, to a three-dimensional retaining wall design automation program.

The design of a general retaining wall involves designing the retaining wall and working on drawings based on the completed design section. After that, the quantity is calculated based on the drawings to calculate the quantity, which is all done in individual steps and is collected later. The design work is carried out by the design team using a program for structural analysis, and the drawing work is carried out with reference to the structural analysis results using a commercialized drawing program. Finally, the quantity is calculated with reference to the completed drawing. Therefore, the design, drawings, and quantity cannot be linked, and errors may occur depending on the worker concerned.

In order to solve this problem, many design automation programs are being developed using the above-described technology. The program is divided into LOD (Level of Development) 100, 200, 300, 400, and 500 according to the precision. LOD 100 is the level of the conceptual design model level, which refers to the level where only graphic surfaces are possible, and LOD 200 is the level to set the outline model. It refers to the level at which the rough quantity and size shape can be set. LOD 300 is a precision shape model level and provides important details and information related to dimensions. LOD 400 is the level of the production model, and it refers to the level that can be manufactured by including details of the structure, combination structure, and installation information.

In the case of the construction field, the 3D design automation programs developed so far were programs below the LOD 300 level, which did not reach the stage where construction was possible and only provided information on the shape of the structure.

The above-described prior art configuration, names, and reference numbers are used limitedly for the description of the prior art.

Republic of Korea Patent No. 10-1695591 'a design method based on civil engineering knowledge using a program library for specifying the location of a model in space' is a design method based on civil engineering using a program library for specifying a location of a model in space. With respect to, a profile building step (step S10) of making a 3D curve and a surface with the profile building means (10); A template model generation step ( step S20) and; 3D model data definition step (step S30) of defining single or multiple 3D model data by generating information classified for each item in the template model as an Excel data sheet with the 3D model data definition means 30 (step S30); The three-dimensional model generating means 40 consists of a three-dimensional model generating step (step S40) of generating a single or multiple models using the 3D model data defined in Excel, so that single or multiple models are collectively transformed. The knowledge-based library construction is not limited by the design method created using the computer program library at a specific location in space, and the model reconstruction time can be easily shortened in the function implementation, design stage, and construction stage, 3 It is a useful invention that not only can implement a knowledge-based library based on the dimensional linear pavement plan, but also can design it in a short time by a small number of workers, which has the special advantage of dramatically reducing the design cost.

Republic of Korea Patent No. 10-0538937 'Steel frame drawing generation system using structure data and AutoCAD' uses structure data and AutoCAD that can automatically generate steel structure drawings with AutoCAD using the result data of commercial structure programs. It is a steel frame drawing system. It automatically reads structural data from the existing commercial structural analysis program, converts it into its own information database, and uses two-dimensional and three-dimensional simulations to enable users to easily select the desired structural cross section, and finally to save the engineer's structural analysis result. It is a steel frame drawing generation system that automatically creates an AutoCAD drawing file.

Republic of Korea Patent No. 10-1801262 'drawing analysis system and method' analyzes the properties of the base floor drawing layer for building design and accumulates only the data necessary for map construction to automatically analyze the drawing layer for floors other than the base floor and map it in order to be able to convert it to A drawing analysis system according to the present invention includes: an extraction unit for storing data attribute values and rules extracted from at least one drawing DB (data base); a map production unit for producing a map by applying the data attribute values and rules; and a storage unit for storing the produced map.

Republic of Korea Patent No. 10-1695591 Republic of Korea Patent No. 10-0538937 Republic of Korea Patent No. 10-1801262

The present invention is a program that is automatically processed by linking the 3D design of the retaining wall structure and the drawings and quantity calculation according to the design result. Model the retaining wall in three dimensions by using it, and automate the drawing of the result, and calculate the quantity based on it. Due to this, it is possible to accurately calculate the shape and quantity of the structure, and it has the advantage of being able to immediately start construction (LOD 400 level) using the design drawings.

In order to solve the above problems, the three-dimensional retaining wall drawing automation program of the present invention includes an initial input step of inputting the project name and initial data of the construction site (S100); A site setting step (S200) of classifying the application site of the retaining wall structure (A); a section setting step (S300) of setting a section of the retaining wall structure (A); An installation shape designation step (S400) of designating a longitudinal installation shape of (A) of the retaining wall structure as a point or a line (Line); a three-dimensional modeling step (S500) of applying the section of the retaining wall structure (A) designated in the section setting step (S300) to the position set in the installation shape designation step (S400); and a starting and ending point designating step (S600) of designating a starting point (A1) and an ending point (A2) of the retaining wall structure (A).

The cross-section setting step (S300) is a step of determining the geometric shape of the retaining wall structure (A), and the retaining wall structure shape including a gravity-type retaining wall, an anti-gravity-type retaining wall, an L-type retaining wall, an inverted T-type retaining wall, and a buttress-type retaining wall is stored. Preferably, it is a step of selecting any one from the retaining wall shape data D100.

It is preferable that the shape information D101 and the attribute information D102 of the structure are input to the retaining wall shape data D100, and the input shape information D101 and the attribute information D102 can be modified and changed.

Preferably, the shape information D101 is information on the size and shape of the structure, and the attribute information D102 is information on material properties of the structure and materials used.

In the three-dimensional modeling step (S500), the structure is created with the section of the retaining wall set in the retaining wall shape data (D100) along the point or the line set in the installation shape designation step (S400). , The cross section of the set retaining wall structure (A) is one side lower edge (A11), one side upper edge (A13), the other lower end edge (A12), the other side upper edge (A14), any one of the center of gravity point (A15) is the point It is preferably generated along the (point) or the line (Line).

It is preferable to be able to calculate, output, and check the quantity required for construction based on the three-dimensional shape of the retaining wall structure (A) after the start and end point designation step (S600).

The geometric shape and cross section of the retaining wall shape data D100 are designed for stability of the ground bearing capacity, stability to activity, stability to fall, and stability of slopes including retaining walls according to the design conditions of the retaining wall structure (A). It is desirable to have cross-sections of a geometric shape and size determined therefrom from which a review is made.

The initial input step (S100), the site setting step (S200), the cross-section setting step (S300), the installation shape designation step (S400), the three-dimensional modeling step (S500), the starting and ending point designation step (S600) is carried out sequentially, but it is desirable to move to the previous stage to be able to modify and supplement it.

The three-dimensional modeling step (S500) is preferably capable of setting the position by rotating and moving the geometric shape of the retaining wall structure (A) along the lateral direction, the front-back direction, and the vertical direction.

It is preferable that the quantity of the retaining wall structure (A) calculated after the starting and ending point designation step (S600) is calculated based on the structurally calculated reinforcement reinforcement and the concrete cross section in the section setting step (S300).

The 3D retaining wall drawing automation program according to the present invention works on the drawings using the cross-sections that have been designed in the structural calculation, but the design process is fast and the quantity errors occur because the quantity is automatically calculated based on the 3D modeled drawings. I never do that. Above all, even if a design change of a structure occurs, drawings and quantity (quantity) can be calculated only by changing the cross section of the structure at the design stage, so drawings and quantity calculation can be performed quickly and accurately.

1 is a representative view of Korean Patent No. 10-1695591
2 is a representative view of Republic of Korea Patent No. 10-0538937
3 is a representative view of Korean Patent No. 10-1801262
4 is a diagram schematically illustrating a system configuration according to an embodiment of the present invention;
5 is a view showing input of a construction project name in the initial input stage according to an embodiment of the present invention;
6 is a view showing input of a field setting step according to an embodiment of the present invention;
7 is a view showing input of an uplink line in the field setting step according to an embodiment of the present invention;
8 is a view showing input of a section setting step according to an embodiment of the present invention;
9 is a view showing input of an installation shape designation step according to an embodiment of the present invention;
10 is a diagram illustrating input of a three-dimensional modeling step according to an embodiment of the present invention;

An embodiment of the three-dimensional retaining wall design automation program according to the present invention will be described in detail with reference to the accompanying drawings. A description will be omitted.

In addition, terms such as first, second, etc. used below are merely identification symbols for distinguishing the same or corresponding components, and the same or corresponding components are limited by terms such as first, second, etc. not.

In addition, the term "coupling" does not mean only when there is direct physical contact between each component in the contact relationship between each component, but another component is interposed between each component, so that the component is in the other component. It should be used as a concept that encompasses even the cases in which each is in contact.

Hereinafter, a three-dimensional retaining wall design automation program according to an embodiment of the present invention will be described in detail with reference to the accompanying tables and drawings.

The three-dimensional retaining wall design automation program of the present invention includes an initial input step of inputting the project name and initial data of the construction site (S100); A site setting step (S200) of classifying the application site of the retaining wall structure (A); Section setting step (S300) of setting the section of the retaining wall structure (A); An installation shape designation step (S400) of specifying the longitudinal installation shape of the retaining wall structure (A) as a point or a line (Line); A three-dimensional modeling step (S500) of applying the cross section of the retaining wall structure (A) designated in the section setting step (S300) to the position set in the installation shape designation step (S400); It includes;

The section setting step (S300) is a step of determining the geometric shape of the retaining wall structure (A). A retaining wall structure including a gravity-type retaining wall, an anti-gravity-type retaining wall, an L-type retaining wall, an inverted T-type retaining wall, and a buttress-type retaining wall is stored. Any one of the shape data D100 is selected.

At this time, the retaining wall shape data D100 is stored in the retaining wall data library L, and the geometric shape and cross-section of the retaining wall shape data D100 depend on the design conditions of the retaining wall structure (A). Design reviews for stability against overturning, stability of slopes including retaining walls are conducted, and the geometrical shape and size of the sections are determined from this.

The shape information D101 and the attribute information D102 of the structure are input to the retaining wall shape data D100, and the input shape information D101 and the attribute information D102 can be modified and changed at any stage during the program.

The shape information D101 is information about the size and shape of the structure, and is about the size and shape information of the structure, and the attribute information D102 is information about the material properties of the structure and the material used, and the compressive strength of concrete , slump value, elastic modulus, etc. As for the reinforcing bar, the tensile strength, elastic modulus, diameter, yield strength, breaking strength, etc. of the structure may be stored.

As such, the present invention enables immediate construction based on drawings and quantities after performing the program (LOD 400 level). This is because, in the retaining wall shape data D100, all characteristic information about the surrounding environment for carrying out construction together with the shape information and attribute information of the structure is stored.

A user may design a structure in three dimensions using all the data stored in the retaining wall shape data D100, and calculate the construction quantity based on this.

The retaining wall shape data D100 includes a road retaining wall standard diagram to facilitate the design of retaining walls applied to highways.

In the three-dimensional modeling step (S500), the structure is created with the section of the retaining wall set in the retaining wall shape data (D100) along the point or line set in the installation shape designation step (S400), but the set retaining wall structure The cross section of (A) is one side lower edge (A11), one upper edge (A13), the other lower edge (A12), the other upper edge (A14), any one of the center of gravity point (A15) is a point or a line ( line) is generated.

After the starting point designation step (S600), the quantity required for construction is calculated based on the three-dimensional shape of the retaining wall structure (A), and it is preferable that the quantity can be output and confirmed.

At this time, the starting point A1 and the ending point A2 of the retaining wall structure A may be specified in the installation shape designation step S400, or may be set in the starting and ending point designation step S600 after the three-dimensional modeling step S500. .

The three-dimensional retaining wall drawing automation program according to the present invention is an initial input step (S100), a site setting step (S200), a section setting step (S300), an installation shape designation step (S400), a three-dimensional modeling step (S500), a starting point The designation step (S600) is performed sequentially, and it is possible to move to the previous step to modify and supplement. In particular, by utilizing the retaining wall data library (L), the most efficient cross-sectional shape and quantity can be efficiently modified and applied.

In addition, it is possible to check whether each step is executed or not through the interface.

In the three-dimensional modeling step (S500), it is preferable to be able to set the position by rotating and moving the geometric shape of the retaining wall structure (A) in the lateral direction, the front-back direction, and the vertical direction.

In the present invention, when designing a structure, the structure can be freely rotated in any of the x-axis, y-axis, and z-axis, vertical and lateral gradients can be set, and a linear structure can be designed.

In addition, in the installation shape designation step (S400), a plurality of points (pnoints) or lines (Line) can be set as curves and straight lines.

It is preferable that the quantity of the retaining wall structure (A) calculated after the starting and ending point designation step (S600) is calculated based on the reinforcing reinforcement and the concrete section calculated in the section setting step (S300).

At this time, the calculated quantity is calculated from all the constituent materials of gravity-type retaining walls, anti-gravity-type retaining walls, L-type retaining walls, inverted T-type retaining walls, and buttress-type retaining walls stored in the retaining wall data library (L). That is, depending on the type of retaining wall, concrete, reinforcing bars, and the amount of filling can be calculated.

In addition, it is possible to check the amount of fill or cut required for the retaining wall structure.

A : Retaining wall structure A1 : View point
A2: End point D100: Retaining wall shape data library
D101: shape information D102: attribute information
S100: Initial input step S200: Field setting step
S300: section setting step S400: installation shape designation step
S500: 3D modeling step S600: Start-end point designation step

Claims (11)

An initial input step of inputting the project name and initial data of the construction site (S100); A site setting step (S200) of classifying the application site of the retaining wall structure (A); a section setting step (S300) of setting a section of the retaining wall structure (A); An installation shape designation step (S400) of designating a longitudinal installation shape of (A) of the retaining wall structure as a point or a line (Line); a three-dimensional modeling step (S500) of applying the section of the retaining wall structure (A) designated in the section setting step (S300) to the position set in the installation shape designation step (S400); A three-dimensional retaining wall automation design program comprising a;
According to claim 1,
The site setting step (S200) is a step of classifying the site where the retaining wall structure (A) is constructed, and includes a highway, a national road, a local road, and a complex. and 3D retaining wall automation design program, characterized in that the installation location is stored by additionally designating the direction of the lower fish.
3. The method of claim 2,
The section setting step (S300) is a step of determining the geometric shape of the retaining wall structure (A), and the retaining wall structure shape including a gravity-type retaining wall, an anti-gravity-type retaining wall, an L-shaped retaining wall, an inverted T-shaped retaining wall, and a buttress-type retaining wall is stored. A three-dimensional retaining wall automation design program, characterized in that it is a step of selecting any one from the retaining wall shape data (D100).
4. The method of claim 3,
The shape information D101 and attribute information D102 of the structure are input to the retaining wall shape data D100, and the input shape information D101 and the attribute information D102 can be modified and changed, characterized in that 3D retaining wall automation design program.
5. The method of claim 4,
The shape information (D101) is information about the size and shape of the structure, and the attribute information (D102) is information on material properties of the structure and materials used, 3D retaining wall automation design program, characterized in that.
6. The method of claim 5,
The three-dimensional modeling step (S500) is
A structure is created with the section of the retaining wall set in the retaining wall shape data D100 along the point or the line set in the installation shape designation step (S400), but the set retaining wall structure (A) One side lower edge (A11), one side upper edge (A13), the other lower end edge (A12), the other upper edge (A14), any one of the center of gravity point (A15) is the point (point) or the line (Line) A three-dimensional retaining wall automation design program, characterized in that it is generated along.
7. The method of claim 6,
3D retaining wall automation design program, characterized in that after the starting and ending point designation step (S600), the quantity required for construction is calculated based on the 3D shape of the retaining wall structure (A), and the quantity output and confirmation are possible.
8. The method of claim 7,
The geometric shape and cross section of the retaining wall shape data D100 are designed for stability of the ground bearing capacity, stability to activity, stability to fall, and stability of the slope including the retaining wall according to the design conditions of the retaining wall structure (A). A three-dimensional retaining wall automation design program, characterized in that the cross-sections are reviewed and whose geometric shape and size are determined.
9. The method of claim 8,
The initial input step (S100), the site setting step (S200), the cross-section setting step (S300), the installation shape designation step (S400), the three-dimensional modeling step (S500), the starting and ending point designation step (S600) 3D retaining wall automation design program, characterized in that it proceeds sequentially, and can be modified and supplemented by moving to the previous stage.
10. The method of claim 9,
The three-dimensional modeling step (S500) is a three-dimensional retaining wall automation design program, characterized in that it is possible to set the position by rotating and moving the geometric shape of the retaining wall structure (A) in the lateral direction, the front-back direction, and the vertical direction. .
11. The method of claim 10,
3D retaining wall automation design, characterized in that the quantity of the retaining wall structure (A) calculated after the starting and ending point designation step (S600) is calculated based on the structurally calculated reinforcement reinforcement and the concrete cross section in the section setting step (S300) program.

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