JP2010044447A - Extraction method of architecture cad data - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for converting drawing data created by use of general-purpose architecture CAD software into a precut drawing capable of being read in an NC machine tool used in a precut factory by simple technique of reading the drawing data as binary data. <P>SOLUTION: All horizontal and vertical straight lines each having a length in a prescribed-value range to a length of a side of a square of a pillar portion are detected, two vertical straight lines each having, in one of both end coordinates of the straight line, a point positioned at a distance not more than a half of a lengthwise/crosswise dimension of a prescribed squared lumber standard from each of both end coordinates of the horizontal straight line are extracted, two straight lines each having the straight line length in the prescribed-value range to the lengthwise/crosswise dimension of the prescribed squared lumber standard are selected from the extracted vertical straight lines, and the horizontal straight line having, in one of both the end coordinates of the straight line, a point positioned at a distance not more than a half of the length of the side of the square of a section of the pillar from the one of both the end coordinates of the selected two vertical straight lines is selected, so that the cross-sectionally square pillar portion of the prescribed squared lumber standard is recognized. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method of converting main parts such as columns and roofs in a metafile in which straight lines are described by coordinate data into CAD data for processing building materials.

  For the purpose of preventing disguise of building confirmation application, the Building Standard Law has been reviewed and it takes time for building confirmation. On the other hand, when the architect designed and supervised a small wooden house, the examination of the structural regulations could be omitted. According to the so-called No. 4 exception, the No. 4 building (under 2 stories wooden, less than 500 square meters: structure With regard to exemption from calculation), applications for confirmation have come down relatively smoothly, and other buildings that require structural calculations have become a social problem with a delay in building confirmation.

  However, the mandatory calculation of the structure of the No. 4 building is under consideration. In any case, so-called design CAD is used for the structural calculation, and the CAD data of the design CAD cannot be used as it is with the pre-cut processing machine in the building material processing company for construction. There is a movement that IAI Japan and the like standardize bidirectional cooperation between design CAD and pre-cut CAD. However, design CAD that can cooperate with pre-cut CAD is expensive and not very popular. Actually, there are many design offices that use free software such as JW-CAD as design CAD, for example, and there are many problems in bidirectional cooperation between design CAD and pre-cut CAD.

  In Patent Document 1, the building component type selection input means extracts a library corresponding to the selected building component type from the library based on the building component type selection input information, and the building component data input means includes: Data relating to the building component input according to the extracted library is recorded as building component data, the manufacturer data table search means searches the manufacturer data table based on the building component data, and the manufacturer data conversion means reads the building data. An integrated CAD system for building component design / manufacturing information is disclosed in which component data is converted into a data code used by the manufacturer, and the manufacturer data output means outputs the manufacturer data.

  Patent Document 2 discloses an input system for acquiring an architectural design of a structure as an automatic layout system that directly acquires data from architectural drawings, blueprints, or CAD (computer-aided design), and the architectural design described above. A structural layout comprising a processing system for converting into a plurality of component positions of a structure and an output system for receiving at least one component position from the processing system and for outputting each component position An apparatus for is disclosed.

In Patent Document 3, there is an integrated drawing creation system that converts drawing data between a plurality of dedicated CAD devices and a comprehensive CAD device that creates a comprehensive drawing. The drawing data on a specific layer of the dedicated CAD device and the specific data Converts the drawing data on a specific layer of the total CAD device corresponding to the layer to each other, converts the drawing data between the dedicated CAD device and the total CAD device, and converts the drawing data created by the dedicated CAD device to the total CAD An integrated drawing creation system for creating an integrated drawing with an apparatus is disclosed.
JP 2004-206193 A Special table 2004-515828 JP-A-8-235243

  In the integrated CAD system for building component design / manufacturing information in Patent Document 1, the building component type selection input means extracts from the library a library corresponding to the selected building component type based on the building component type selection input information. For example, in the case of a window, the position is managed by a unique number, and the attribute data of the manufacturer data is serial number, window number, window type, window type, window type code, series, selfish, corner, strength, Data corresponding to items of fire prevention, soundproofing, total width, total height, width, height, FL, frontage, dakimakura, metal fittings, screen door, and conversion to precut CAD is difficult with this data structure.

  In the apparatus for structural layout of Patent Document 2, it is said that the processing system 14 converts the building design into a plurality of component positions of the structure. The information, digital drawing data files 36, 36A, and UBC 44 data are combined, and the processing system 14 is configured to include components 40 within the structure 32 (eg, structural members 40A, windows 40B, doors 40C, electrical elements 40D, piping elements 40E). , Heating, ventilation, air conditioning elements 40F, etc.) are calculated and generated. The dimensional positions of each component 40 are digitized and automatically transferred to the output system 16. " No specific conversion method is disclosed or suggested.

  The integrated CAD device of Patent Document 3 unifies the drawings created by different types of CAD devices by converting the inherent data format of the incompatible building-side CAD device and the equipment-side CAD device into the DXF format. Although it is described that it can be handled, there is no disclosure or suggestion of a method for specifically converting the inherent data format to the DXF format.

  The problem to be solved by the present invention is to provide a method for converting drawing data created using general-purpose architectural CAD software, for example, JW-CAD, into a precut drawing that can be read by an NC processing machine used in a precut factory. It is.

In the pre-cut CAD data conversion method of the present invention, in order to convert an architectural CAD drawing into a pre-cut drawing, a data conversion for generating a pre-cut drawing for pre-cut CAD by reading an architectural CAD file having a plurality of layers as a binary data file. A method,
The scale data of the drawing is described at a predetermined position of any layer of the architectural CAD file,
According to the following procedure, a pillar section having a square cross section and a predetermined square bar standard is recognized. (Procedure 1) All the straight lines in the horizontal and vertical directions having a length within a specified value range with respect to the length of one side of the square of the column part are detected in all layers.
(Procedure 2) One of the horizontal straight lines is selected, and a point located at a distance of half or less of the vertical and horizontal dimensions of the predetermined square bar standard from each of the both end coordinates of the horizontal straight line has one of the end coordinates of the straight line. Two straight lines in the vertical direction are extracted.
(Procedure 3) From the straight lines in the vertical direction extracted in the above procedure, two straight lines whose straight line lengths are within the specified range with respect to the vertical and horizontal dimensions of the predetermined square bar standard are selected.
(Procedure 4) A point that is less than half the length of one side of the square of the cross section of the column from the two vertical straight line end coordinates selected in the above step is one of the straight line end coordinates. Select a straight line.

  According to the data conversion method of the present invention, a file created by an architectural CAD that is not versatile in the construction industry is converted into CEDXM (CEDXM (registered trademark) format or text format pre-cut sketch data that is versatile in the construction industry. By converting, it is possible to generate CEDXM (CEDXM (registered trademark) format and text format precut drawing data without using expensive CEDXM (registered trademark) type architectural CAD, contributing to the cost reduction of the construction industry it can.

  The best mode for carrying out the present invention will be described below in detail with reference to the drawings. In the following description, components having the same function are denoted by the same reference numerals, and repeated description thereof is omitted.

  FIG. 1 shows a pre-cut CAD data conversion system including the periphery. First, a CAD file supplied from an external design CAD 1 is input to the CAD data conversion device 3, and then converted into a meta file 4 for data analysis.

  In the CAD data conversion device 3, the metafile 4 is converted into CEDXM (registered trademark) CAD data by the conversion unit 5 and sent to the structural calculation device 9, and the precut CAD device 6 converts the data into a precut processing data file. After the conversion, the data is provided to the precut processing machine 7 as processing data.

  On the other hand, the CEDXM (registered trademark) data sent to the structural calculation device 9 is subjected to a content check as a file for the building confirmation application system 12, and if correction is necessary, the precut processing machine 7 is corrected after being corrected by the route 10. Are provided as corrected machining data and are also provided to the building confirmation application system 12.

  The CEDXM data undergoes a content check as a file for the building confirmation application system 12, and if correction is not required, data transfer by the route 10 is not performed and the data is provided to the building confirmation application system 12 as it is.

  FIG. 2 is an example of a basic plan by JW-CAD. In the case of JW-CAD, there are 16 layers in one group, and there are 16 groups, so a total of 256 layers can be used. However, the usage of layers is not constant because design CAD designers such as architectural offices can decide freely.

  Therefore, detecting a layer and detecting symbol data such as a pillar or a wall is not a practical method because it requires trial and error for each layer.

  Therefore, in the present invention, in order to execute data extraction from the entire file without any distinction of layers and convert it into data that can be used in precut CAD, by analyzing binary data of a CAD file of a design CAD, for example, the JW-CAD CAD file, The coordinate data of the start point / end point of the desired straight line is detected and converted to pre-cut CAD data.

  If the scale data of a drawing is additionally written at a predetermined position on the screen, even an architectural CAD drawing created by a different operator can be processed with a unified processing program.

  In this embodiment, “scale = 1/50” is described in the upper center portion of the screen. However, the scale data can be any position in the drawing as long as the scale data can be recognized uniformly by the management software. It may be arranged.

Further, as a specific reading procedure, the following methods 1 to 4 can be considered.
(Procedure 1) All the straight lines in the horizontal and vertical directions having a length within a specified value range with respect to the length of one side of the square of the column part are detected in all layers.
(Procedure 2) One of the horizontal straight lines is selected, and a point located at a distance of half or less of the vertical and horizontal dimensions of the predetermined square bar standard from each of the both end coordinates of the horizontal straight line has one of the end coordinates of the straight line. Two straight lines in the vertical direction are extracted.
(Procedure 3) From the straight lines in the vertical direction extracted in the above procedure, two straight lines whose straight line lengths are within the specified range with respect to the vertical and horizontal dimensions of the predetermined square bar standard are selected.
(Procedure 4) A point that is less than half the length of one side of the square of the cross section of the column from the two vertical straight line end coordinates selected in the above step is one of the straight line end coordinates. Select a straight line.

  The specified value range in the above (Procedure 1) and (Procedure 3) may be set to a range of ± 10% with respect to the standard length, for example, but this depends on the CAD drawing creator. There is. If the range is set too narrow, the straight line recognition rate may decrease. In this case, the set value is changed as appropriate within a range of ± 50% for safety, and work efficiency is improved. be able to.

  3A to 3C are examples of column material symbols in the design CAD. FIG. 3A is a portion including the periphery of the column material, and FIG. 3B is a line from 13a to 13f. It is an enlarged view of only the constituted pillar material.

  FIG.3 (c) is an enlarged view of the pillar material comprised by the lines 13a, 13b, and 13d-13f which deleted only the line 13c in FIG.13 (b).

  For example, if JW-CAD is used for design CAD, and the sketch file containing FIG. 13B is compared with the sketch CAD file containing FIG. 13C, only the portion of the line 13c is missing. A data format expressing 13c can be detected.

FIG. 4 is a screen in which the JW-CAD file is opened with a text editor. From the left, the text line number, 16 sets of 2-byte code, and binary code are displayed in this order. In an actual program, it is not necessary to open the CAD file with a text editor. In the program, 2-byte code, 1- or 2-byte binary code, and using this display method, the drawing of FIG. 2 is read as a metafile. If the line 13c is erased and read as a metafile, the 14th and 15th words are changed from “6C” “6B” to “E8” and “67” in the line of the 151st row. You can see that it has been rewritten.

  In the 156th line, the tenth word is replaced from “C2” to “52”.

  In the 359th line, the 13th word is replaced from “49” to “A6”, and the 2nd word position in the 1023th line is changed from “B8” to “B7”.

  Next, in the column symbol in FIG. 3B, when the file from which the line 13a is deleted and the file that has been read as a metafile are compared, the 14th and 15th words in the 151st line are compared. Is rewritten from “6C” and “6B” to “A4” and “6A”, and the 10th word of the 156th line is rewritten from “C2” to “A4”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added to the 13th word position on the 297th line, and the “00” on the 300th line is added. 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ”has been deleted.

  Further, the 13th word on the 359th line is changed from “49” to “61”, and the 2nd word position on the 1023rd line is changed from “B8” to “B7”.

  Next, in the column symbol in FIG. 3B, when the file from which the line 13b is deleted and the file that has been read as a metafile are compared, the 14th and 15th words in the 151st line are compared. Is rewritten from “6C” and “6B” to “DC” and “69”, and the 10th word of the 156th line is rewritten from “C2” to “92”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” was added to the 13th word position on the 297th line, and it was at the 13th word position on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” has been deleted.

  Further, the 13th word position on the 359th line is changed from “49” to “6F”, and the 2nd word position on the 1023th line is changed from “B8” to “B7”.

  Further, in the column material symbol of FIG. 3B, when comparing the file from which the line 13d is deleted and the file from which the file before deletion is read as a metafile, the 14th and 15th words are found in the 151st line. “6C” “6B” is rewritten from “DC” and “69”, and the 10th word of the 156th line is rewritten from “C2” to “8C”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” was added to the 13th word position on the 297th line, and it was at the 13th word position on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” has been deleted.

  Further, the 13th word position on the 359th line is changed from “49” to “76”, and the 2nd word position on the 1023th line is changed from “B8” to “B7”.

  Further, in the column material symbol of FIG. 3B, when the file from which the line 13e is deleted and the file that has been read as a metafile are compared, the 14th and 15th words are found on the 151st line. “6C” “6B” is rewritten from “40” and “6A”, and the 10th word of the 156th line is rewritten from “C2” to “9E”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” was added to the 13th word position on the 297th line, and it was at the 13th word position on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” has been deleted.

  Further, the 13th word position on the 359th line is changed from “49” to “66”, and the 2nd word position on the 1023th line is changed from “B8” to “B7”.

  Further, in the column material symbol of FIG. 3B, when comparing the file from which the line 13f is deleted and the file from which the file before deletion is read as a metafile, the 14th and 15th words are found in the 151st line. “6C” “6B” is rewritten from “78” and “69”, and the 10th word in the 156th line is rewritten from “C2” to “80”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” was added to the 13th word position on the 297th line, and it was at the 13th word position on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” has been deleted.

  Further, the 13th word position on the 359th line is changed from “49” to “81”, and the 2nd word position on the 1023rd line is changed from “B8” to “B7”.

  FIG. 4 is a screen display example in which a file created by JW-CAD is opened by a binary editor. 16 words 14a are successively displayed in order from the left end of the screen, and a text reading 14b is displayed on the right end thereof.

  FIG. 5 is a relationship diagram of each element of the pillar material and the binary code corresponding to each element. In each table, the original data of the binary code seen when each element 13a to f describing the column material is individually erased is shown in the upper part, and the change data is shown in the lower part.

  When a JW-CAD file with a 13a line and an erased JW-CAD file are opened with a binary editor, the 14th and 15th words are rewritten from "6C" and "6B" to "A4" and "6A" The 10th word on the 156th line is rewritten from “C2” to “A4”, the 13th word on the 359th line is changed from “49” to “61”, and the 2nd word position on the 1023rd line is “B8”. "" To "B7".

  When a JW-CAD file having a 13b straight line and an erased JW-CAD file are opened with a binary editor, the 14th and 15th words are changed from “6C”, “6B” to “DC” on the 151st line. And the 69th word on the 156th line is rewritten from “C2” to “92”, the 13th word position on the 359th line is changed from “49” to “6F”, and the 1023rd line The 2-word position is changed from “B8” to “B7”.

  When the JW-CAD file having the 13c straight line and the erased JW-CAD file are opened with the binary editor, the 14th and 15th words in the 151st line are changed from “6C” “6B” to “E8”. In the 156th line, the 10th word is replaced from “C2” to “52”, and in the 359th line, the 13th word is changed from “49” to “A6”. The second word position on the 1023rd line is changed from “B8” to “B7”.

  When a JW-CAD file with a 13d straight line and an erased JW-CAD file are opened with a binary editor, the 14th and 15th words are changed from “6C”, “6B” to “DC” on the 151st line. And the 69th word on the 156th line is rewritten from “C2” to “8C”, the 13th word position on the 359th line is changed from “49” to “76”, and the 1023rd line The 2-word position is changed from “B8” to “B7”.

  When a JW-CAD file having a straight line 13e and an erased JW-CAD file are opened by a binary editor, the 14th and 15th words are changed from "6C" "6B" to "40" on the 151st line. Is rewritten to "6A", the 10th word of the 156th line is rewritten from "C2" to "9E", the 13th word position of the 359th line is changed from "49" to "66", and the 1023rd line The 2-word position is changed from “B8” to “B7”.

  When a JW-CAD file having a 13f straight line and an erased JW-CAD file are opened with a binary editor, the 14th and 15th words are changed from “6C” “6B” to “78” in the 151st line. And the 69th word on the 156th line is rewritten from “C2” to “80”, the 13th word position on the 359th line is changed from “49” to “81”, and the 1023rd line The 2-word position is changed from “B8” to “B7”.

  FIG. 6 shows the coordinate data of the start / end points of two parallel straight lines by using the roof slope data together, and the binary data of the roof portion having the two parallel straight lines as components is converted to CEDXM ( This is an example of conversion into pre-cut drawing data in CEDXM (registered trademark) format or text format.

  Here, two straight lines 15a and 15c having a preset gradient are detected, and two straight lines 15b and 15d in the vertical direction having contact points with these two straight lines are further detected as the roof 15. Can be recognized.

  FIG. 7 is an example of conversion of a closed space. Here, the coordinate data of the start point / end point of the straight line forming the closed space is detected, and the binary data of the closed space is converted into CEDXM (CEDXM (registered trademark) format or text format precut map data. The rectangular closed space is composed of at least three straight lines, but does not constitute a closed space unless there are three intersections.

  However, in the present invention, even if there are three straight lines with no intersection when the figure is enlarged, the error range is half of one side of the column, for example, a column of 105 mm, 52.5 mm or less (in the case of a 105 mm column, If it is less than half of 105 mm when the length of one side of the column cross-section square is calculated from the coordinate data of the detected start / end points of the straight line, all are recognized as intersection points, and a polygonal room is formed by the aggregate of the triangles. The program consists of beams and roofs. In addition, it is possible to discriminate characters such as a part of the name and the like that cannot be distinguished by attaching data exclusive to the side receiving the profit from the data link.

  Among the encircled line (FL ± 0) 15 in the center left of FIG. 2, binary data obtained by opening a JW-CAD file with the bottom line 15a erased with a text editor, binary data before the bottom line 15a is erased, and 14 and 15 words in the 151st row are rewritten from “6C” and “6B” to “14” and “69”, and the 10th word in the 156th row is changed from “C2” to “74”. Has been rewritten.

  Furthermore, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added to the 13th word position on the 297th line, and the 300th line “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” has been deleted from the 13th word.

  In addition, the 13th word on the 359th line is changed from “8B” to “49”, and the second word on the 1023rd line is rewritten from “B7” to “B8”.

  Furthermore, from the position of the 13th word on the 8409th line, “F0 51 B8 1E 85 1E C0 00 D8 A3 70 3D AA 45 40 EC 8F C2 F5 28 3C 40 C0 00 D8 A3 70 3D AA 45 40 01 80 00 00 00 00 01 02 00 00 00 05 00 00 00 00 00 00 ”is erased.

  Next, binary data obtained by opening a JW-CAD file in which a vertical line 15b on the left side of the boxed box (FL ± 0) 15 on the left side in FIG. Comparing the binary data before erasure of 15b, the 14th and 15th words in the 151st row are rewritten from “6C” and “6B” to “40” and “6A”, and the 15th row 14 words are rewritten from “C2” to “98”.

  Also, “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added from the position of the 13th word on the 297th line, and the 300th line “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” at the 13th word position is deleted.

  Further, the binary data obtained by opening the JW-CAD file in the text editor with the horizontal line 15c in the upper part of the enclosed line (FL ± 0) 15 on the left side of the center in FIG. 2 and the upper horizontal line 15c are deleted. Comparing the previous binary data, the 14th and 15th words in the 151st row are rewritten from “6C” and “6B” to “40” and “6A”, and the 14th word in the 156th row is changed. “C2” is rewritten to “9E”.

  “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added from the position of the 13th word on the 297th line, and the 13th word on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” at the eye position has been deleted.

  In addition, binary data obtained by opening a JW-CAD file in which a vertical line 15d on the right side of the enclosing line (FL ± 0) 15 in the center left side of FIG. 2 is deleted with a text editor, and a horizontal line 15c on the upper side Comparing the binary data before erasure, the 14th and 15th words in the 151st row are rewritten from “6C” and “6B” to “DC” and “69”, and the 14th word in the 156th row. Is rewritten from “C2” to “8C”.

  “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added from the position of the 13th word on the 297th line, and the 13th word on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” at the position of the eye is deleted, and the 13th word on the 359th line is changed from “49” to “ It has been changed to 76 ".

  Further, binary data obtained by opening a JW-CAD file in which a vertical line 15d on the right side of the boxed line (FL ± 0) 15 in the center left side of FIG. 2 is deleted with a text editor, and a vertical line 15d on the right side. 14th and 15th words on the 151st row are rewritten from “6C” and “6B” to “40” and “6A”, and the 14th word on the 156th row The word is rewritten from “C2” to “98”.

  “7B 4E 34 CE C0 1B FF 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” is added from the position of the 13th word on the 297th line, and the 13th word on the 300th line. “00 00 00 00 00 00 F0 3F 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00” at the position of the eye is deleted, and the 13th word on the 359th line is changed from “49” to “ 6B ".

  FIG. 8 is a conversion example of a wall line penetrating a column. Here, a straight line penetrating the column portion is specified as a wall line by referring to coordinate data constituting the column portion, and binary data of the wall line is converted into CEDXM (CEDXM (registered trademark) format or text format pre-cut image. Convert to diagram data.

  First, the pillar material symbol 13 is specified, and the quadrangle and the diagonal line constituting the pillar material symbol 13 are detected.

  Next, by detecting a straight line 17 passing through the pillar material symbol 13, the straight line 17 can be specified as a wall line.

  9A shows an example of a CAD drawing of a single straight line drawn on the upper left side of the screen, FIG. 9B shows an example of a CAD drawing of a single straight line drawn on the upper center of the screen, and FIG. ) Is an example of a CAD drawing of one straight line drawn in the center of the left side of the screen.

  FIGS. 10A to 10H are lists of binary data obtained by opening the CAD file of FIG. 9A with a binary editor and dividing the CAD file every 16 bytes.

  The portion from the sixth word of the 960th line to the fifth word of the 980th line in FIG. 10G is a portion describing a straight line. Among these, “43” in the 13th word of the 970th line and the 5th word of the 980th line indicates a data delimiter, so “6th to 12th words of the 970th line” “4A 07 3C-42 F6 0D B7” and “E900 00 42 F6 0D B7” from the 14th word on the 970th line to the 4th word on the 980th line indicate the coordinates of the straight line.

  As a coordinate display method in the CAD file, there are a method of determining the reference point and displaying the absolute position of each coordinate, a method of displaying the position coordinate from the starting point, and the like. Is (0.038, -0.025) and the right end is (0.062, -0.025).

  FIGS. 11A to 11I are lists of binary data obtained by opening the CAD file of FIG. 9B with a binary editor and dividing the CAD file every 16 bytes.

  The portion from the sixth word of the 960th line to the fifth word of the 980th line in FIG. Among these, “43” in the 13th word of the 970th line and the 5th word of the 980th line indicates a data delimiter, so “6th to 12th words of the 970th line” “34 DF 3D-42 A5 4E A8” and “DE EC 99 42 A5 4E A8” from the 14th word on the 970th line to the 4th word on the 980th line indicate the coordinates of the straight line.

  As a coordinate display method in the CAD file, there are a method of determining the reference point and displaying the absolute position of each coordinate, a method of displaying the position coordinate from the starting point, and the like. Is (0.038, -0.048) and the right end is (0.062, -0.048).

  FIGS. 12A to 12I are lists of binary data obtained by opening the CAD file of FIG. 9C with a binary editor and dividing the CAD file every 16 bytes.

  The portion from the sixth word of the 960th line to the fifth word of the 980th line in FIG. Among these, “43” in the 13th word of the 970th line and the 5th word of the 980th line indicates a data delimiter, so “6th to 12th words of the 970th line” "7E 66 78 -43 97 75 A9" and "90 F2 8A 43 97 75 A9" from the 14th word of the 970th line to the 4th word of the 980th line indicate the coordinates of the straight line, The coordinates of a straight line can be specified by two sets of three words separated by “43” or “−43”.

  As a coordinate display method in the CAD file, there are a method of determining the reference point and displaying the absolute position of each coordinate, a method of displaying the position coordinate from the starting point, and the like. Is (0.202, -0.048) and the right end is (0.225, -0.048). Here, the unit is meters.

  As described in the explanation of FIG. 7, in the present invention, even if there are three straight lines having no intersection when the figure is enlarged, the error range is recognized as an intersection up to a distance half of one side of the column. . In other words, if it is a 105 mm column, it should be 52.5 mm or less (in the case of a 105 mm column, less than half of 105 mm when the length of one side of the square of the column is calculated from the coordinate data of the detected start / end points of the straight line). It is a program that recognizes all as intersections and constructs polygonal rooms, beams, and roofs by a collection of triangles.

  Here, if the scale ratio is 1/50 and one side of the column is 105 mm, it is 0.105 m, so it is 0.0021 on the drawing, so the coordinates are half of 0.0021, that is, within 0.00105. Coordinates with errors are regarded as intersections and can be converted from architectural CAD drawings to pre-cut CAD drawings by recognizing them as closed spaces.

  A switch that is attached to the housing at a low cost without using special software for design CAD data that has been widely used can be converted into CEDXM (CEDXM (registered trademark) format or text-format precut drawing data. Therefore, it is possible to contribute to the IT and efficiency of the construction industry.

Pre-cut CAD data conversion system including surroundings Example of basic plan by JW-CAD (A) Example of column material symbol in design CAD (b) Enlarged view of column material symbol part (c) Diagram with one side removed from column material symbol Example of a screen displayed when a file created with JW-CAD is opened with a binary editor Binary code representation for each column component Extraction example of roof part Extraction example of closed space (A) Periphery of wall line (b) Extraction figure of wall line (A) CAD drawing example of one straight line drawn to the upper left side of the screen (b) CAD drawing example of one straight line drawn to the upper center of the screen (c) CAD drawing example of a straight line of books Binary file 000000-000300 in Fig. 9 (a) The binary file 000310-000610 in FIG. The binary file 000620-000920 in FIG. Binary file 000930-000C30 in Fig. 9 (a) Binary file 000C40-000F40 in Fig. 9 (a) Binary file 000F50-001250 in Fig. 9 (a) The binary file 001260-001280 in FIG. Binary file 000000-000300 in Fig. 9 (b) Binary file 000310-000610 in FIG. 9B The binary file 000620-000920 in FIG. Binary file 000930-000C30 in Fig. 9 (b) Binary file 000C40-000F40 in Fig. 9 (b) Binary file 000F50-001250 in Fig. 9 (b) The binary file 001260-001280 in FIG. Binary file 000000-000300 in Fig. 9 (c) The binary file 000310-000610 in FIG. The binary file 000620-000920 in FIG. Binary file 000930-000C30 in Fig. 9 (c) Binary file 000C40-000F40 in Fig. 9 (c) Binary file 000F50-001250 in Fig. 9 (c) The binary file 001260-001280 in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Design CAD, 2 ... Data transmission path, 3 ... Precut CAD, 4 ... Metafile conversion function, 5 ... CEDXM conversion function, 6 ... Precut data generation function, 7 ... Precut processing machine, 8 ... Data transmission path, 9 ... Structural calculation software, 10 ... Data transmission path, 11 ... Data transmission path, 12 ... Building confirmation application procedure, 13 ... Column material symbol, 13a-13f ... Column material symbol element, 14a ... Binary display, 14b ... Text display, 15 ... Hand scanner, 16 ... closed space, 16a to 16d ... closed space element, 17 ... wall line.

Claims (1)

A data conversion method for reading a building CAD file having a plurality of layers as a binary data file and generating a precut drawing for precut CAD,
The scale data of the drawing is described at a predetermined position of any layer of the architectural CAD file,
A method of converting precut CAD data, wherein a pillar section having a square section and a predetermined square bar standard is recognized by the following procedure.
(Procedure 1) All the straight lines in the horizontal and vertical directions having a length within a specified value range with respect to the length of one side of the square of the column part are detected in all layers.
(Procedure 2) One of the horizontal straight lines is selected, and a point located at a distance of half or less of the vertical and horizontal dimensions of the predetermined square bar standard from each of the both end coordinates of the horizontal straight line has one of the end coordinates of the straight line. Two straight lines in the vertical direction are extracted.
(Procedure 3) From the straight lines in the vertical direction extracted in the above procedure, two straight lines whose straight line lengths are within the specified range with respect to the vertical and horizontal dimensions of the predetermined square bar standard are selected.
(Procedure 4) A point that is less than half the length of one side of the square of the cross section of the column from the two vertical straight line end coordinates selected in the above step is one of the straight line end coordinates. Select a straight line.

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