KR20220123201A - Method for estimating material using the method of manufacturing 3D drawing using 2D drawing for construction - Google Patents

Abstract

The present invention relates to a method for manufacturing a three-dimensional drawing using a two-dimensional drawing for construction, which is able to vertically place a floor plan and a cross-sectional diagram to rapidly and precisely manufacture a three-dimensional drawing matching the floor plan, the cross-sectional diagram, and an elevation. According to the present invention, a method for a worker to manufacture a three-dimensional drawing from a two-dimensional drawing by using a three-dimensional program installed in a worker terminal comprises: a step of loading a floor plan and a cross-sectional diagram with classified layer onto a three-dimensional program, selecting and activating a needed layer from the floor plan and the cross-sectional diagram, and arranging the floor plan and the cross-sectional diagram; a step of setting a thickness in a vertical direction on the layer falling under the floor surface of the floor plan; a step of extending the layer falling under a wall in the floor plan for a determined height in a vertical direction, and generating an extended drawing; a step of placing the extended drawing on the cross-sectional diagram with a reference point in the center; a step of horizontally extending the layer falling under a roof in the cross-sectional diagram and forming a roof, and generating a temporary three-dimensional drawing; a step of additionally extending the layer falling under the wall of the extended drawing up to a position required in the cross-sectional diagram; a step of placing the elevation on the temporary three-dimensional drawing, and forming a passage unit on a position of the temporary three-dimensional drawing corresponding to the elevation, and generating a three-dimensional drawing; and a step of setting layers for each floor in the three-dimensional drawing, and setting detailed layers with a wall or a slab in each floor.

Description

{Method for estimating material using the method of manufacturing 3D drawing using 2D drawing for construction}

The present invention relates to a method for estimating the quantity of materials required for construction using a 3D drawing production method using 2D drawings for construction based on a plan view, a cross-sectional view, and an elevation view.

BIM (Building Information Modeling) refers to a three-dimensional design technology that has recently become a hot topic in the construction industry. means

Recently, the trend of design advancement and energy-saving/environment-friendly building construction through the use of open BIM is accelerating internationally.

However, in the construction of small and medium-sized buildings, it is still a reality to construct 2D drawings based on floor plans and cross-sections. A problem occurred.

Therefore, there is a need for a 3D drawing production method using 2D drawings for construction that can quickly and accurately produce 3D drawings based on a floor plan, a cross-sectional view, and an elevation view.

On the other hand, the importance of accurately calculating the quantity of materials required in the construction of a building is well known. This is an important matter for decision-making in the planning stage of a building and for setting the budget range.

The conventional quantity estimation relied on manual work based on 2D drawings, and the quantity calculation is very different depending on the level of error or know-how of the operator. there was.

Republic of Korea Patent Registration No. 10-1473956 Republic of Korea Patent Registration No. 10-1335109

The present invention is to solve the above problems, and by arranging the plan view and cross-section vertically, 3D drawing production using 2D drawing for construction that can quickly and accurately produce 3D drawing that matches plan view, section and elevation view The purpose of this method is to provide a quantity estimation method using a 3D drawing production method using 2D drawings for construction that can accurately predict the quantity of materials required by selecting a detailed layer from the 3D drawing completed by this method.

The quantity estimation method using the 3D drawing production method using 2D drawings for construction according to the present invention for achieving the above object is a method in which an operator produces 3D drawings from 2D drawings using a 3D program installed in a worker terminal. A quantity estimating method using the method, comprising: loading a layered plan view and a cross-sectional view into a 3D program, selecting a required layer from the plan view and cross-sectional view, and activating the layer to organize the plan view and cross-sectional view; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction; arranging the expanded drawing in the cross-sectional view around a reference point; forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing; further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or a slab in each layer; completing the 3D drawing, including, selecting a detail layer from the completed 3D drawing checking the volume of the 3D program; and calculating a quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor.

The quantity estimating method using the 3D drawing production method using the 2D drawings for construction according to another embodiment of the present invention is the amount using the method in which the worker uses the 3D program installed in the worker terminal to produce the 3D drawings from the 2D drawings A method for estimating, comprising: loading a layered plan view and a cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view, to organize the plan view and cross-sectional view; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction; arranging the expanded drawing in the cross-sectional view around a reference point; further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view; generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the expanded drawing; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or slab in each layer, wherein forming the roof includes setting vertices and corner points in a roof plan view, and the vertex determining a point that is vertically downward from the limiting plane of the solar circle in the true north direction as a reference vertex, and determining another vertex as a confirmation vertex; connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface; checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and when the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line; checking the volume of the detailed layer in a 3D program; and calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor.

The quantity estimating method using the 3D drawing production method using the 2D drawings for construction according to another embodiment of the present invention is the amount using the method in which the worker uses the 3D program installed in the worker terminal to produce the 3D drawings from the 2D drawings A method for estimating, comprising: loading a layered plan view and a cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view, to organize the plan view and cross-sectional view; arranging the plan view in the cross-sectional view around a reference point; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view; forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or a slab in each layer; completing the 3D drawing, including, selecting a detail layer from the completed 3D drawing checking the volume of the 3D program; and calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor.

The quantity estimating method using the 3D drawing production method using the 2D drawing for construction according to another embodiment of the present invention is a method in which a worker uses a 3D program installed in a worker terminal to produce a 3D drawing from a 2D drawing. A quantity estimating method, comprising: loading a layered plan view and a cross-sectional view into a 3D program, selecting and activating a necessary layer from the plan view and cross-sectional view, and organizing the plan view and cross-sectional view; arranging the plan view in the cross-sectional view around a reference point; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view; generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the plan view in which a layer corresponding to a wall extends in a vertical direction; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or slab in each layer, wherein forming the roof includes setting vertices and corner points in a roof plan view, and the vertex determining a point that is vertically downward from the limiting plane of the solar circle in the true north direction as a reference vertex, and determining another vertex as a confirmation vertex; connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface; checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and when the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line; checking the volume of the detailed layer in a 3D program; and calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor.

In addition, after the step of arranging the extension drawing or the step of setting the thickness, the method may further include the step of forming a staircase based on the cross-sectional view or the additionally arranged cross-sectional view, and after the step of generating the temporary 3D drawing The method may further include forming an opening in the roof.

The present invention can quickly and accurately produce a 3D drawing consistent with a plan view, a section view, and an elevation view by arranging the expanded drawing in the section view or placing the plan view vertically in the section view, and the operator can use the 2D drawing and the 3D drawing more quickly and accurately It can be constructed, and there is an effect that it is possible to easily form a roof having a non-uniform cross section in one direction.

In addition, there is an effect of accurately calculating the quantity of materials required by selecting a detailed layer from the completed 3D drawing as a 3D drawing production method using 2D drawings for construction.

1 is a plan view of a first floor according to an embodiment of the present invention.
2 is a plan view of the first floor in which a necessary layer is selected and activated according to an embodiment of the present invention;
3 is an enlarged view prepared in a first floor plan view arranged according to an embodiment of the present invention.
4 is an enlarged view arranged in a cross-sectional view arranged around a reference point on the first floor according to an embodiment of the present invention.
5 is a view showing expanded views arranged in a rearranged cross-sectional view with respect to each floor reference point according to an embodiment of the present invention.
6 is a view showing an additional extension of a layer corresponding to each layer wall according to an embodiment of the present invention;
7 is a view showing the formation of a roof according to an embodiment of the present invention.
8 to 10 are views illustrating a process of forming an opening in a roof according to an embodiment of the present invention.
11 and 12 are views showing a step formation process according to an embodiment of the present invention.
13 to 15 are views showing a process of forming a passage in a temporary 3D drawing on which an elevation view is arranged according to an embodiment of the present invention.
16 and 17 are 3D views according to an embodiment of the present invention.
18 and 19 are cutaway 3D views according to an embodiment of the present invention.
20 to 23 are diagrams illustrating detailed layers selected in a 3D drawing according to an embodiment of the present invention;
24 to 26 are views illustrating a process of forming a roof having non-uniform cross-sections in one direction according to an embodiment of the present invention.
27 and 28 are views showing that a curved roof surface is formed on a roof according to an embodiment of the present invention.
29 and 30 are views showing that a plurality of triangular roof surfaces are formed on a roof according to an embodiment of the present invention.

In describing the preferred embodiment of the present invention in detail, if it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

A 3D drawing production method using 2D drawings for construction according to an embodiment of the present invention is a method in which an operator uses a 3D program installed in a worker terminal to produce a 3D drawing from a 2D drawing, the layered plan view and loading the cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view to organize the plan view and cross-sectional view; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction; arranging the expanded drawing in the cross-sectional view around a reference point; forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing; further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting layers for each layer in the 3D drawing, and setting detailed layers as walls or slabs in each layer.

A 3D drawing production method using 2D drawings for construction according to another embodiment of the present invention is a method in which an operator uses a 3D program installed in a worker terminal to produce a 3D drawing from a 2D drawing, the layered plan view and loading the cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view to organize the plan view and cross-sectional view; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction; arranging the expanded drawing in the cross-sectional view around a reference point; further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view; generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the expanded drawing; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or slab in each layer, wherein forming the roof includes setting vertices and corner points in a roof plan view, and the vertex determining a point that is vertically downward from the limiting plane of the solar circle in the true north direction as a reference vertex, and determining another vertex as a confirmation vertex; connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface; checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and when the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line.

FIG. 1 is a view showing a first floor plan according to an embodiment of the present invention, and FIG. 2 is a view showing a first floor plan in which a necessary layer is selected and activated according to an embodiment of the present invention.

Operators use 3D programs (eg Rhino, Solidworks, Cad, Catia, and Blender, etc.) You can make drawings.

The first step is the process of organizing the plan and cross-section by loading (importing) the layered plan and cross-section into a 3D program, selecting and activating the required layer in the plan and cross-section. 1 shows components divided into various layers, such as a wall 10 , a door 11 , and a column 12 . If necessary layers such as the wall 10, the pillar 12, and the outline 13 are selected and activated in FIG. 1, a plan view of the first floor can be obtained as shown in FIG. At this time, if it is a two-story building and the planar structure of the first and second floors is different, at least a first floor plan and a second floor plan are required, and if an attic is provided under the roof, an attic floor plan will also be added.

In addition, if the layers are not divided by walls and doors in the floor plans and cross-sectional views of each floor, a process of dividing and setting the layers in the floor plans and cross-sectional views of each floor is required first. In this case, different colors may be set for each layer.

3 is an enlarged view in which the thickness is set on the floor surface and the wall is formed by a certain height in a plan view of the first floor organized according to an embodiment of the present invention.

The second step is a process of setting the thickness in the vertical direction (z-axis direction) of the layer corresponding to the floor in the plan view. The height and thickness of the floor may be different, and the value shown in the cross section for each layer You can set the height and thickness.

The third step is a process of generating an expanded drawing by extending a layer corresponding to a wall in the plan view by a predetermined height in the vertical direction. At this time, if it is a two-story building and there is an attic, the wall can be extended in the vertical direction to the height of the bottom of the second floor floor as shown in the cross section, Floor Expansion Drawings and Clearances You may need an attic expansion plan made from an attic floor plan.

4 is an expanded view arranged in a sectional view centered on a reference point on the first floor according to an embodiment of the present invention, and FIG. 5 is a view showing expanded views arranged in a sectional view centered on each floor reference point according to an embodiment of the present invention. to be.

The fourth step is a process of arranging the expanded drawing in a cross-sectional view centered on the reference point. In the case of a two-story building with an attic, first, the first floor expansion drawing 31 in the organized cross-sectional view 25 centered on the first floor reference point 21 . ), arrange the second floor expansion drawing 32 in the clearance section 25 centered on the second floor reference point 22, and the attic expansion drawing 33 in the clearance section 25 centering on the attic reference point 23 ) is placed.

FIG. 6 is a view showing that a layer corresponding to each wall is further expanded according to an embodiment of the present invention.

Step 6 is a process of further extending the layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view after step 4 or step 5 to be described later. In the process of generating the expanded drawing of step 3, the walls are This is the step of cutting off the excess part when the wall is expanded beyond the bottom height of each floor in the case of not extending to the bottom height of the floor accurately, or when the wall is expanded in the process of producing the expansion drawing of the third step. In the third step, it is possible to increase the speed of the 3D modeling work by vertically extending the layer corresponding to the wall to an arbitrary height lower than the bottom height of the floor of each floor.

7 is a view showing the formation of a roof according to an embodiment of the present invention, FIGS. 24 to 26 are views showing a process of forming a roof whose cross section is not constant in one direction according to an embodiment of the present invention, and FIGS. 27 and 28 is a view showing that a curved roof surface is formed on the roof according to an embodiment of the present invention, and FIGS. 29 and 30 are views showing that a plurality of triangular roof surfaces are formed on the roof according to an embodiment of the present invention.

The fifth step is to form the roof 15 by horizontally expanding the layer corresponding to the roof 15 in the cross-sectional view and create a temporary 3D drawing, or temporarily by forming a roof whose cross section is not uniform in one direction in the expanded drawing This is the process of creating a 3D drawing. At this time, if the cross section of the roof is not constant in one direction, accurate confirmation and correction may be required because the information of the 2D roof cross section may not be accurate. Accurately implemented 3D roofs provide significant assistance to workers in building construction.

Forming a roof whose cross section is not uniform in one direction includes steps 5-1, 5-2, 5-3, and 5-4, and step 5-1 is a vertex in the roof plan view (51) and a corner point 52 are set, and a point that is vertically downwardly closest to the normal north direction solar winding oblique limiting surface 55 among the vertices 51 is determined as the reference vertex 51a, and another vertex 51 is selected. It is a process of determining the confirmation vertex 51b. At this time, the vertex 51 , the corner point 52 , the reference vertex 51a and the confirmation vertex 51b may be multiple, and the reference vertex 51a is the most vertically downward from the direct north direction solar winding diagonal limiting surface 55 . From the nearest point, it can be determined as the preferential reference vertex 51a that does not require correction, and the confirmation vertex 51b is the preferential confirmation vertex that needs correction from the point furthest vertically downward from the solar right event limiting surface 55 in the true north direction ( 51b).

In the case of a roof having one reference vertex 51a, a confirmation vertex 51b, and four corner points 52 (not formed on one plane), step 5-2 is a reference vertex 51a and two The first roof surface 56 is formed by connecting the corner points 52 , and the second roof surface 57 is formed by connecting the reference vertex 51a and two other corner points 52 . At this time, in the case of a roof having a plurality of reference vertices 51a, confirmation vertices 51b, and corner points 52, a plurality of roof surfaces will also be formed.

Step 5-3 is a process of confirming whether the confirmation vertex 51b is located on the straight line 58 where the first roof surface 56 and the second roof surface 57 meet, and Step 5-4 is the confirmation vertex ( If 51b) is not located on the straight line 58, it is a process of moving the confirmation vertex 51b up and down to position it on the straight line 51b. At this time, in the case of a roof having a plurality of reference vertices 51a, confirmation vertices 51b and corner points 52, from the preferential reference vertex 51a, steps 5-2, 5-3 and 5 - By performing step 4, the priority confirmation vertex 51b is checked and corrected.

If step 5-1, step 5-2, step 5-3, and step 5-4 are not performed as in the present invention, a curved roof surface is formed on the roof as shown in FIGS. 27 and 28, or 29 and 30, a number of triangular roof surfaces are formed on the roof, which causes a serious problem in that the construction period is lengthened along with an increase in the construction cost.

8 to 10 are views illustrating a process of forming an opening in a roof according to an embodiment of the present invention.

The tenth step is a process of forming the opening 16 in the roof 15 after the fifth step, and is a step required when a skylight is formed in the roof 15 or the shape of the roof 15 is partially changed. 8 to 10 , it can be seen that the opening 16 is formed in the roof 15 and a wall is additionally formed on the side of the opening 16 .

11 and 12 are views illustrating a step formation process according to an embodiment of the present invention.

The ninth step is a process of forming a staircase based on a cross-sectional view or an additionally arranged cross-sectional view after the fourth or fifth step, and is not necessarily possible only after the fourth step or the fifth step, but is also sufficiently possible after the sixth step. In this case, by inactivating some layers, such as walls, so that they do not appear on the screen, it is possible to secure the convenience of drawing the stairs.

13 to 15 are views illustrating a process of forming a passage in a temporary 3D drawing on which an elevation view is disposed according to an embodiment of the present invention.

The seventh step is a process of generating a 3D drawing by arranging the elevation 40 in the temporary 3D drawing, and forming the passing part 46 at the position of the temporary 3D drawing corresponding to the elevation 40. By forming an entrance door, skylight, or window on the outer wall of a building, and by arranging the elevation view 40 in a temporary 3D drawing spaced apart at regular intervals, there is an advantage that the passage portion 46 can be formed at an accurate position. It may proceed in the same manner as the process of forming the opening 16 in the roof 15 of the tenth step.

Step 8 is to set the layers for each floor in the completed 3D drawing (for example, it can be set to various names such as 1F, 2F, PH or roof), and set detailed layers with walls, slabs or beams on each floor ( For example, it can be set to various names such as wall, beam, stair, foundation, column, slab). The eighth step may be set collectively after the completion of the 3D drawing, or may be individually set after completion of the extended drawing of the third step or fourth step and/or the temporary 3D drawing of the fifth step or sixth step. By setting the layer and the detailed layer in this way, the volume of the corresponding layer and the detailed layer can be accurately calculated, and accordingly, the amount of material such as concrete or reinforcing bar can be accurately calculated.

16 and 17 are 3D views according to an embodiment of the present invention, viewed from different directions, and FIGS. 18 and 19 are cutaway 3D views according to an embodiment of the present invention, cut in transverse and longitudinal directions. will be. A building construction worker who is provided with a 3D drawing completed through steps 1 to 10 can construct a building more accurately in a much shorter time than a worker who is simply provided with a floor plan, a cross-sectional view, and an elevation view.

A 3D drawing production method using 2D drawings for construction according to another embodiment of the present invention is a method in which an operator uses a 3D program installed in a worker terminal to produce a 3D drawing from a 2D drawing, the layered plan view and loading the cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view to organize the plan view and cross-sectional view; arranging the plan view in the cross-sectional view around a reference point; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view; forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting layers for each layer in the 3D drawing, and setting detailed layers as walls or slabs in each layer. In this case, the above-described components in the embodiment of the present invention may be equally applied.

A 3D drawing production method using a 2D drawing for construction according to another embodiment of the present invention is a method in which an operator uses a 3D program installed in a worker terminal to produce a 3D drawing from a 2D drawing, in which the layers are separated arranging the plan view and cross-section by loading the plan view and the cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and the cross-sectional view; arranging the plan view in the cross-sectional view around a reference point; setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view; vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view; generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the plan view in which a layer corresponding to a wall extends in a vertical direction; generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and setting a layer for each layer in the 3D drawing, and setting a detailed layer as a wall or slab in each layer, wherein forming the roof includes setting vertices and corner points in a roof plan view, and the vertex determining a point that is vertically downward from the limiting plane of the solar circle in the true north direction as a reference vertex, and determining another vertex as a confirmation vertex; connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface; checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and when the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line. In this case, the above-described components in the embodiment of the present invention may be equally applied.

20 to 23 are diagrams illustrating detailed layers selected in a 3D drawing according to an embodiment of the present invention.

The quantity estimating method using the 3D drawing production method using the 2D drawings for construction according to the present invention is detailed in the 3D drawings completed according to the 3D drawing production method using the 2D drawings for construction according to the embodiment of the present invention. an 11th step of selecting a layer and checking the volume of the detailed layer in a 3D program; and a twelfth step of calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor.

According to the 3D drawing production method using 2D drawings for construction according to an embodiment of the present invention, layers are set for each layer in the completed 3D drawing (for example, 1F, 2F, PH or roof, etc. can be set to various names) ), setting detailed layers with walls, slabs, and beams in each floor (for example, you can set various names such as wall, beam, stair, foundation, column, slab, etc.) because this is different. 20 is a view showing when the walls of the first floor (1F), the second floor (2F), the attic (PH) and the roof are selected as the detailed layer, and FIG. 21 is the first floor ( It is a view when selecting the slab of the foundation of 1F), the second floor (2F), the attic (PH) and the roof (Roof), and FIG. 22 is a detailed layer of the first floor (1F) It is a drawing that appears when a beam and a column are selected.

Step 11 is a process of checking the volume of the detailed layer by selecting the detailed layer. The volume of the detailed layer is automatically calculated and displayed in a 3D program (eg, Rhino, etc.).

Step 12 is a process of calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor, and converting materials required according to the detailed layer (wall, beam, stair, foundation, column, slab, etc.) The coefficients are pre-calculated. That is, it is possible to accurately calculate the quantity of materials such as concrete and reinforcing bars required for building construction.

The above description is merely illustrative of the technical idea of the present invention, and various modifications and variations may be made by those of ordinary skill in the art to which the present invention pertains without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10: wall 11: door
12: pillar 13: outline
15: roof 16: opening
20: floor 21: 1st floor reference point
22: 2nd floor reference point 23: Attic reference point
25: Clearance Section 31: First Floor Expansion Drawing
32: 2nd floor expansion plan 33: Attic expansion plan
40: elevation view 46: passing part

Claims (6)

In the quantity estimating method using a method in which a worker produces a 3D drawing from a 2D drawing by using a 3D program installed in the worker terminal,
arranging the plan view and cross-sectional view by loading the layered plan view and cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view;
setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view;
generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction;
arranging the expanded drawing in the cross-sectional view around a reference point;
forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing;
further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view;
generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and
In the 3D drawing, setting a layer by layer, and setting a detailed layer as a wall or slab in each layer; completes the 3D drawing, including,
selecting a detailed layer from the completed 3D drawing and checking the volume of the detailed layer in a 3D program; and
Calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor;
In the quantity estimating method using a method in which a worker produces a 3D drawing from a 2D drawing by using a 3D program installed in the worker terminal,
arranging the plan view and cross-sectional view by loading the layered plan view and cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view;
setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view;
generating an expanded drawing by expanding a layer corresponding to a wall in the plan view by a predetermined height in a vertical direction;
arranging the expanded drawing in the cross-sectional view around a reference point;
further expanding a layer corresponding to the wall of the expanded drawing to a position required in the cross-sectional view;
generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the expanded drawing;
generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and
In the 3D drawing, setting a layer by layer, and setting a detailed layer as a wall or slab in each layer; includes,
Forming the roof,
setting vertices and corner points in the roof plan view, determining a point that is vertically downwardly close to the limiting plane of the direct north direction of sunlight among the vertices as a reference vertex, and determining other vertices as confirmation vertices;
connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface;
checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and
If the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line; and completing the 3D drawing,
selecting a detailed layer from the completed 3D drawing and checking the volume of the detailed layer in a 3D program; and
Calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor;
In the quantity estimating method using a method in which a worker produces a 3D drawing from a 2D drawing by using a 3D program installed in the worker terminal,
arranging the plan view and cross-sectional view by loading the layered plan view and cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view;
arranging the plan view in the cross-sectional view around a reference point;
setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view;
vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view;
forming a roof by horizontally expanding a layer corresponding to the roof in the cross-sectional view, and generating a temporary 3D drawing;
generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and
In the 3D drawing, setting a layer by layer, and setting a detailed layer as a wall or slab in each layer; completes the 3D drawing, including,
selecting a detailed layer from the completed 3D drawing and checking the volume of the detailed layer in a 3D program; and
Calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor;
In the quantity estimating method using a method in which a worker produces a 3D drawing from a 2D drawing by using a 3D program installed in the worker terminal,
arranging the plan view and cross-sectional view by loading the layered plan view and cross-sectional view into a 3D program, selecting and activating a required layer in the plan view and cross-sectional view;
arranging the plan view in the cross-sectional view around a reference point;
setting a thickness in a direction perpendicular to the layer corresponding to the floor in the plan view;
vertically extending a layer corresponding to a wall in the plan view to a position required in the cross-sectional view;
generating a temporary 3D drawing by forming a roof having a non-uniform cross section in one direction on the plan view in which a layer corresponding to a wall extends in a vertical direction;
generating a 3D drawing by arranging an elevation in the temporary 3D drawing, and forming a passage in a position of the temporary 3D drawing corresponding to the elevation; and
In the 3D drawing, setting a layer by layer, and setting a detailed layer as a wall or a slab in each layer; includes,
Forming the roof,
setting vertices and corner points in the roof plan view, determining a point that is vertically downwardly close to the limiting plane of the direct north direction of sunlight among the vertices as a reference vertex, and determining other vertices as confirmation vertices;
connecting the reference vertex and two corner points to form a first roof surface, and connecting the reference vertex and two other corner points to form a second roof surface;
checking whether the check vertex is located on a straight line where the first roof surface and the second roof surface meet; and
When the confirmation vertex is not located on the straight line, moving the confirmation vertex up and down to position it on the straight line; and completing the 3D drawing,
selecting a detailed layer from the completed 3D drawing and checking the volume of the detailed layer in a 3D program; and
Calculating the quantity required for building construction by multiplying the volume of the detailed layer by a conversion factor;
According to claim 1,
forming a staircase based on the cross-sectional view or the additionally arranged cross-sectional view after the step of arranging the expanded view; and forming an opening in the roof after generating the temporary 3D drawing.
4. The method of claim 1 or 3,
Quantity estimation method using a 3D drawing production method using 2D drawings for construction, comprising; forming an opening in the roof after the step of generating the temporary 3D drawing.

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