JP3859487B2 - Integrated database CAD system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention can grasp the quantity and share the data by using the CAD system on the personal computer, and the CAD and the specification / quantity are unified, and the data flow from the design information to the estimate / construction information is unified. As a database CAD system that can improve the efficiency and labor saving of work such as the efficiency of creating design books, and improve productivity and quality, it is possible to link and integrate architecture, equipment, and structure with three DB-CAD systems. The integrated database CAD system.
[0002]
[Prior art]
  Conventionally, the pattern (drawing) information as information on building production has been generally transmitted by "paper". On the other hand, in recent years, with the progress of computerization in each area of building production, CAD is actively used, and the immediate purpose is to improve the efficiency of drawing and the quality of drawing expression. As described above, most of the use range of CAD remains within the area of each proper for design or construction for the purpose.
[0003]
  From the 1980s to the early 1990s, many companies, including general contractors, developed “integrated CAD for design and construction”. The common features of these were (1) those based on minicomputers and EWS. (2) Each company has created the parameters of the attributes separately. (3) Picking up and summing up is completed within the system. (4) Mainly after the implementation design stage. (5) The operator performs the operation.
[0004]
  However, paying attention to the fact that the greatest utility of computerization such as CAD information is the diversion of data, it takes place at the initial stage of the project to make use of its characteristics to improve the efficiency of building production. Attempts have also been made to distribute design information while exchanging data along each stage of production.
[0005]
  For example, the architectural 3D-CAD system that the applicant previously filed as Japanese Patent Application No. 2000-52731 can use commercially available 3D-CAD software as it is, as shown in FIG. -Connect CAD system 1 and original DB (database) 2 with mutual interface 4, and connect original DB 2 with related system 3 such as quotation system, ordering system, construction drawing system, etc. on personal computer. Building system 3D-CAD1 can be used to make direct links to design work from planning to basic / implementation in related systems, estimation / ordering work, and construction drawing creation work.
[0006]
  In this way, the designer uses the architectural system 3D-CAD1 to proceed with the design work. As a result, the fittings and finish data are accumulated in the original DB2, and the necessary parts are extracted from the original DB2. Used for estimation, ordering, construction drawing creation, etc.
[0007]
  The exchange of data between the CAD and the external DB is usually performed by converting the data into text data in CSV (comma separated value) format. As the interface 4, the architectural system 3D is used by using the Access Link function of specific software. -It was assumed that data was directly written / read from the DB1 in the CAD1 to the original DB2.
[0008]
  In this way, a direct link between design work from planning to basic / implementation in the related system 3 using the attribute function of the architectural 3D-CAD 1 on a personal computer, estimation / ordering work, and construction drawing work Plan. In other words, the opening and finishing data stored in the original DB2 is output to various estimation systems and joinery / finishing tables in the design department, as well as various systems in the downstream estimation / construction department. Used.
[0009]
  By extracting the part with RC attribute from the design model, it can be used as a skeleton diagram creation model, but in this architectural 3D-CAD system, the effect of the attribute that the object has is linked with its own DB. Thus, building elements such as columns, beams, and openings are accumulated, and various attributes such as area and specifications are accumulated in the original DB. Therefore, when a model corresponding to each stage of design is created, it is possible to grasp the floor area, the finished area such as the wall and ceiling, the number of parts, and the rough estimate at the same time. The designer can proceed with rational design that meets the customer's needs while viewing them. On the other hand, in the estimation / accumulation department, those numerical data can be used effectively. In addition to inputting directly into the estimation system, it can also be used to check data from the estimation office.
[0010]
  Further, as shown in FIG. 33, the facility DB-CAD system, which the applicant previously filed as Japanese Patent Application No. 2000-223964, has a personal computer 7 incorporating CAD 6 software for creating facility diagrams and a unique DB ( Database) 2 is a system that supports the creation of construction drawings / completion drawings, estimates, etc. downstream from design drawings upstream of the building equipment field.
[0011]
  Enter and store device / equipment specifications from PC 7, associate graphic information of design drawing with original DB2 device / equipment information, layout information of device / equipment, quantity information of equipment, equipment from design drawing Any one or more of the opening information is output to the original DB 2 and any one or more of drawing data, specifications data, estimation data, and construction data are extracted.
[0012]
  In addition, information on the specifications / arrangement / quantity of equipment / equipment and quantity information on materials / equipment will be handed over to the checkout system as text-based information, and design drawings will be transferred to construction / finished drawings as design (drawing) information. Do.
[0013]
  In addition, the original DB 2 has a job registration function, a device / appliance specification registration / editing function, and various output data creation functions, and the CAD 6 for creating equipment diagrams refers to the equipment / appliance specification information registered in the original DB 2. Functions, Linking function of equipment / apparatus and symbol registered in original DB, Discharging function of equipment / apparatus arrangement information to original DB, Discharging function of equipment opening information to original DB, equipment It has a quantity discharge function and an attribute addition function necessary for quantity discharge.
[0014]
  This equipment-based DB-CAD system can easily create construction drawings from each design drawing, saves labor and can manage the proper ordering of parts, and can start construction plans more quickly than before. The device table / equipment table and the quantity on the drawing can be matched, and various device table expressions (device table creation according to the system flow) are possible, improving the quantity recognition (cost awareness) in the design. As a result, design quality is improved.
[0015]
  Furthermore, as a structural DB-CAD system, there is one that has been filed as Japanese Patent Application No. 9-188965 and patented as Japanese Patent No. 3094211, and as shown in FIG. 34, the structural DB (database) -CAD8 is Centering on the 3D building model, it functions as a drawing CAD on the one hand and links to the database on the other hand. Specifically, when a drawing is created by CAD, the drawing information is automatically stored as character data in the chassis DB via the building model. Conversely, if the data in the chassis DB is changed, it is automatically reflected in the drawing. The
[0016]
  Of the structural design information of the input data content to the structure DB-CAD 8, general information on the building, information on the material, and member cross-section information are stored as an ACCESS file at the time of input. On the other hand, information on the building shape and the arrangement of members is held as a CAD three-dimensional model during an input operation. By holding the arrangement information in the CAD during the input operation, matching by sharing information between the drawing and the axis diagram can be realized with a practical level of response.
[0017]
  In this structural DB-CAD system, the general building information, material information, and member cross-section information among the structural design information are stored as files in a specific format at the time of input, while the information on the building shape and member arrangement is , A database that is stored as a CAD three-dimensional model at the time of input, and a CAD that sweeps out the information stored as the CAD data into a file of the specific format by batch processing when linked with an external system, Are unified into a certain format.
[0018]
  According to this structural DB-CAD system, the structural design department should pursue the efficiency of design work by unifying structural design information by utilizing the case database CAD with a specific format file of this system, which is a three-dimensional CAD. Can do. In the design stage, the plan result is automatically input to the chassis database, thereby generating the original data of the structure calculation and structure diagram. Since various structural design drawings and structural calculations can be automatically coordinated via the chassis database, design work can be made more efficient.
[0019]
  Output diagrams include floor plans, axis drawings (automatic creation), and reinforcing bar detail drawings (automatic creation). In addition, there are steel detail drawings (automatic creation), section lists (semi-automatic creation), and frame DB output. A layout function for creating various mixed drawings is also provided.
[0020]
[Problems to be solved by the invention]
  By the way, it is necessary to take the consistency of the architecture / structure / equipment information in the design, but the CAD system for these architecture / structure / equipment was not integrated into one, and it was not popularized because of hardware / software lease Costs, maintenance costs, etc. The CAD system was expensive, CAD was not widespread at the construction site, so there was no data collection, and the estimation was often carried out by hand. The electronic data was not used, and the operator needed not only the CAD operation but also the deep knowledge of both the working design drawing and construction drawing creation. In addition, it is necessary to master the construction order etc., but the following factors can be considered.
[0021]
  This is only the exchange of picture data in the DWG or DXF format, and the exchange of data having no attributes is continued. Also, it is mainly two-dimensional, and it takes time and effort to correct the garbled phenomenon by conversion, and it is difficult to check the consistency by superimposing the pattern data in two dimensions.
[0022]
  As described above, data exchange between different CAD softwares is usually possible only for picture information. Moreover, in most cases, three-dimensional information can be exchanged only in plane information ignoring the height. As a result, in spite of designing a single building, for example, even if one piece of information on a building is taken, there is a disadvantage that it cannot be shared as the same information by the architecture, structure, and equipment.
[0023]
  The object of the present invention is to eliminate the inconvenience of the conventional example and develop a CAD information linkage function for data linkage by 3 systems DB-CAD of architecture / structure / equipment. By creating objective data to derive a logical solution by consistency inconsistency by interference check between shape data and specification information It is an object of the present invention to provide an integrated database CAD system that can be expected to have an effect of enhancing the consistency by centralizing information and taking a natural match or improving the efficiency of collation work.
[0024]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention firstly provides a CAD system on a personal computer.TheAnd
  Architectural DB-CAD consisting of a combination of architectural 3D-CAD system and DB (database) that can use commercially available 3D-CAD software as it is for finishing, joinery, etc.,
  Equipment DB-CAD consisting of a combination of a personal computer with a built-in CAD software for creating equipment diagrams and a DB (database) for equipment / equipment, piping, ducts, wiring, etc .;
  Concerning pillars, beams, slabs, etc., it consists of three DB-CADs, a structure DB-CAD that functions as a drawing CAD on the one hand, and links to a DB (database) on the other hand, centering on a 3D building model. Database CAD systemIn,
  Equipment DB-CAD gives equipment 3D information (three-dimensional information of equipment) to construction DB-CAD, and equipment DB, and equipment DB-CAD gives equipment members, columns, beams, walls, ceilings, etc. Return 3D interference information with building materials, and plan information (plan view, room area, room name, ceiling height, floor height), building shape information, building member information, building cross-section information, etc. Information transportation means between the building DB-CAD and the equipment DB-CAD, which gives frame information;
  Position information for building structure information such as building shape information, building member information, and building cross-section information is given from structure DB-CAD to equipment DB-CAD, and a hole is drilled from structure DB-CAD to structure DB-CAD. Information return means between the structure DB-CAD and the equipment DB-CAD, which returns the information on the opening of the housing (sleeve), etc.
  Between the building DB-CAD and the structure DB-CAD, there is provided an information passing means between the building DB-CAD and the structure DB-CAD for transferring building information such as building shape information, building member information, building cross-section information,
  In the architecture DB-CAD,
  Means for automatically determining interference between equipment members and building members taken from equipment DB-CAD;
  There is provided means for superimposing and displaying the frame information taken from the structure DB-CAD and the frame information created by the architecture DB-CAD,
  In the structure DB-CAD,
  Means for superimposing and displaying the frame information taken from the construction DB-CAD and the frame information created by the structure DB-CAD
The gist of this is to provide.
[0025]
  Secondly, it is for realizing data linkage between different CAD software, and means for exchanging data described in character information (DB information) to exchange three-dimensional data with attributes, and the CAD side to read Then, the gist is to provide a reproduction means for reproducing the attribute / pattern based on the information.
[0026]
  According to the present invention, it is intended to realize data linkage between different CAD software, ensuring consistency and unifying data, and becomes a means for three-dimensional superposition. For this purpose, character information (DB information) ) Is exchanged to realize three-dimensional data exchange with attributes, and on the CAD side to read in, the method of reproducing attributes and patterns based on the information is used to ensure the incorporation of information and ensuring consistency Can do.
[0027]
  In the present invention, the specification / quantity is unified, and the flow of data from design information to estimate / construction information can be unified. This means that the inconsistency of information can be eliminated, and the flow of data from consistent design information to estimate / construction information can be unified.
[0028]
  An objection to lead logical solution by conformity inconsistency by interference check of shape data and specification information, while it was a popular person who relied on the intuition and experience of engineers to confirm by superimposing drawings in the past. It is now possible to create realistic data.
[0029]
  In architecture-structure, it is possible to ensure the integrity of the chassis, and in architecture-equipment, it is possible to confirm and secure the consistency between the equipment content and the architecture plan, and to reproduce the architecture plan at the start of drawing. It can reproduce the frame at the start of drawing and return the frame opening information to the structure.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram showing an information flow showing one embodiment of the integrated database CAD system of the present invention, and FIG. 2 is a conceptual explanatory diagram of the same.
[0031]
  In the figure, 10 is an architectural DB (database) -CAD, 11 is an equipment DB-CAD, 12 is a structural DB-CAD, and as described above, each of them is a CAD system (architectural 3D-CAD1, architectural system 3D) on the personal computer 7. By using CAD7 for equipment drawing creation and 3D-CAD8), it is possible to grasp the quantity and share the data in a unique way by linking with the original DB2, and the design and quantity are unified with the CAD. The data flow from information to estimate and construction information can be unified, and the efficiency of design work can be improved, labor saving and productivity and quality can be improved.
[0032]
  The present invention includes three DB-CADs, such as a construction DB-CAD 10 relating to such finishing and joinery, a facility DB-CAD 11 relating to equipment / equipment, piping / duct / wiring, etc., and a structure DB-CAD 12 relating to columns, beams, and slabs. Connect each other.
[0033]
  In such cooperation, handling of attribute data is a key point. For example, in the structure of a pillar, it can be understood that it is a function of a pillar when four line segments are gathered and seen as a quadrangle by human eyes, but on a CAD, it is only a set of lines, or just a square. Or In the present invention, an attribute is given as CAD so that the type, material, size, etc. of the column can be discriminated.
[0034]
  This is how to read each object one by one from the database, but this is centered on grid information. This way of reading ensures consistency, and after that, it is limited to pillars, beams, walls, slabs, etc. that are responsible for the structure, and the equipment is in the form of electrical equipment, sanitary equipment, air conditioning equipment. To limit the scope of responsibility. Otherwise, each object will come and go to interact with the building.
[0035]
  As described above, data described in character information (DB information) is exchanged to realize three-dimensional data exchange with attributes, and the reading CAD side needs to reproduce attributes and designs based on the information. is there. For this purpose, the objects in the mutual positional relationship are matched, and for this purpose, the reference origin and the grid are output and adjusted. Each system outputs all grid information (symbol, coordinates of start and end points). Output grid information for each drawing unit.
[0036]
  The reading side determines the position and vector of the partner's core from the intersection of three of the partner's cores (one that crosses two parallel lines, for example X1, X2, Y1), and compares it with your own core Then, adjustment is made and the member is arranged. This correspondence is applied, for example, when a model is created on a one-to-one basis for architecture and structure.
[0037]
  As shown in FIG. 17, assuming that the grids describing the building are on the actual data such as X1,2,3,4,5, Y1,2,3, write the data to each other, The positional relationship defines the starting point, for example, by taking out any three of X1, 2, Y1, the coordinates of the intersection can be specified, and the coordinates of the intersection and what is actually written in it in the program As a result of comparison, there is a relative position on the other party's database, so the relative position is calculated and read as X1,2, Y1 in itself, and the relative position of the point is calculated in the program Output as.
[0038]
  As shown in FIG. 18, even if the grids are separated, there is only one data, so there is no problem if any three can be taken out. As shown in FIG. 19, the relationship between the own model and the partner model is not 1: 1. Even in this case, there is no problem if any three of them can be taken out. Further, as shown in FIG. 20, the relative position can be specified if the center position and the radius are specified even in the case of an arc grid.
[0039]
  First, cooperation between building DB-CAD10 and equipment DB-CAD11 is demonstrated. As shown in FIG. 3 and FIG. 4, the facility DB-CAD 11 gives the building DB-CAD 10 with the facility 3D information (three-dimensional information of the facility) as an interference check between the building and the facility. 3D interference information is returned from the CAD 10 to the equipment DB-CAD 11. Through the database from the equipment DB-CAD11, the construction DB-CAD10 is reconstructed in the form that reproduces the equipment. Fix the defective part again with the equipment.
[0040]
  Specifically, as a linkage of equipment 3D information to architecture (equipment DB-CAD11 → architecture DB-CAD10), lighting equipment, air-conditioning equipment, sanitary equipment / equipment, piping, ducts from a comprehensive diagram created with equipment DB-CAD11 Information such as size, coordinates, file name, file path, figure number (ID), etc. is written in the equipment 3D database (EPM_DAT.mdb).
[0041]
  This data is taken into the building DB-CAD 10 and data is generated as a three-dimensional equipment member. This makes it possible to effectively check the installation status of equipment members and check interference with building members on the building DB-CAD 10.
[0042]
  As the facility 3D data creation method, (1) the electrical, sanitary, and air conditioning drawings are overlapped to create a comprehensive diagram of the facility as shown in FIG. (At this point, the overall adjustment within the facility is complete.) (2) Press the facility 3D data creation button, and (3) a dialog will appear. Press the browse button to determine the output destination folder. (4) Next, input the output file name, and (5) input the floor of the output target data. (6) Press the OK button when ready to create equipment 3D data at the specified location. This data is linked to the building DB-CAD 10.
[0043]
  Next, as the cooperation of the interference information to the equipment (architecture DB-CAD10 → equipment DB-CAD11), the construction DB-CAD10 checks the interference between the equipment members taken in by 3D cooperation and the construction materials such as columns, beams, walls, and ceilings. Can be done for each part. Furthermore, information such as the figure number (ID), file name, and file path of the equipment member extracted by this interference check is output from the construction DB-CAD 10 to the outside as a text file.
[0044]
  FIG. 21 shows a screen when receiving the MDB of the equipment DB-CAD 11 of the part that is to be interfered with the equipment member on the screen showing the incorporation of the equipment member in the building DB-CAD 10 although the example is different.
[0045]
  Select “Linkage / Piping Duct Linkage / Read Equipment DB” from the menu bar in Architectural DB-CAD10, then read the MDB received from the person in charge of equipment design, check “drawing name” and “floor” and read “ Select “Target Member”. As a result, as shown in FIG. 22, the members of the facility DB-CAD 11 are arranged with reference to an arbitrary intersection of cores.
[0046]
  Layer in which equipment members are taken in ・ Electric equipment: CHCK-E
                                    ・ Hygiene equipment: CHCK-P
                                    ・ Air conditioning equipment: CHCK-M
[0047]
  FIG. 23 is a screen showing an interference check between an equipment member and a building member. In the building DB-CAD 10, “Cooperation / Piping duct / Interference check” is selected from the menu bar, and “Checked building member” and “Checked equipment” are selected. Select "Parts" and press "Interference Check". Thereby, as shown in FIG. 24, the “member” and “ID” of the building member and the facility member that interfere with the “interference member ID” are displayed.
[0048]
  As shown in FIG. 25, since the equipment member that interferes with the building member on the plan view is displayed in red, when the interference member on the interference check screen is selected, the selected member is also selected on the plan view.
[0049]
  On the other hand, if explanation is given from the equipment side, the equipment DB-CAD 11 can also read the interference information and easily confirm which equipment member in which drawing is interfering with the building.
[0050]
  The outline of the 3D interference data capturing method will be described. (1) When the interference data capturing command is executed and the interference information output from the building DB-CAD 10 is read, (2) the interference information confirmation screen is displayed. ) The total number of interference members for each floor is displayed in the interference information confirmation screen. (4) The operator selects the floor to be confirmed and presses the confirmation button. (5) When the confirmation button is executed, the target drawing data is automatically opened, and the color of the interference member is changed and displayed. By the above operation, the facility member that interferes with the building member can be easily identified on the facility DB-CAD 11 side.
[0051]
  In addition, as shown in FIG. 5, from the construction DB-CAD 10 to the equipment DB-CAD 11, plan information such as a plan view, a room area, a room name, a ceiling height, a floor height, and frame information when starting drawing is given. The facility DB-CAD 11 can start drawing based on it.
[0052]
  As such linkage of building information to equipment (architecture DB-CAD10 → equipment DB-CAD11), floor plan data (DWG data) for each floor from three-dimensional modeling data created by the architecture DB-CAD10 And cut into equipment DB-CAD11.
[0053]
  The plan view data capturing method will be described. As shown in FIG. 13, (1) click a file open icon and select DWG data. In this case, a DWG drawing (* .dwg) is selected as the file type. When a DWG drawing to be edited is selected, a DWG import screen is displayed. First, a conversion table is selected.
[0054]
  After selecting the conversion table, check if “Arrangement Layer” is set to “Architecture”, then match “Paper Size” and “Scale” and click “OK” when the setting is completed. Is opened. Thereby, data conversion is performed so that it can be easily processed as an architectural drawing for facilities such as layer integration and line color unification.
[0055]
  In the equipment DB-CAD 11, in addition to the DWG import table, a conversion table (see FIG. 15) for efficiently reading DXF data and CAD We'll data is prepared as standard.
[0056]
  Next, the sheet is moved so that the room name and room area taken in from the building DB-CAD 10 can be recognized by the equipment DB-CAD 11.
  First, (2) layer NO. Select and press “OK”. (3) Select "Settings"-"Sheet Function"-"Move Copy" or right-click on the sheet tab and select "Move Copy" from the menu that appears (4) A dialog will appear , Mode: Select “Move (M)”, Destination: “Room Area” and press “OK”. (5) Enter the specified point. (Enter: same position) is displayed, so press “Enter”. As a result, the room name and the room area information on the base sheet are moved onto the room area sheet. Similarly, the room name on the room area sheet is moved to the room name sheet. After selecting the character you want to move, select "Settings"-"Sheet Function"-"Move Copy" and the previous dialog will be displayed. Select the mode: "Move (M)" and the move destination "Room Name". Press “OK”. As a result, the room name information on the room area sheet is moved onto the room name sheet.
[0057]
  (7) Although the area is necessary when used as the equipment DB-CAD 11, it is not necessary to print at the time of output, so all areas are made auxiliary figures. Select all the sheet tabs while holding down the Shift key. (8) When the sheet tab is highlighted in black and is right-clicked, the non-display of the dialog is selected. (9) Since only the selected sheet can be edited, the room area sheet tag is clicked to display only the room area as shown in FIG.
[0058]
  (10) Select “Setting” — “Color, Line” — “Change” from the menu. “Select a figure” is displayed. Enclose all figures with the mouse and select Enter, then press Enter on the keyboard. (11) Since the attribute change dialog is displayed, select the auxiliary figure line from the line type list and press OK. With the above operation, the room area is made into an auxiliary figure.
[0059]
  Incorporation of building information by IFC data is output as building information such as room areas, room names, ceiling heights, floor heights, columns, beams, slabs, walls, etc. created by the building DB-CAD10 as IFC data. Read with DB-CAD11. Note that IFC (Industry Foundation Classes) is the definition of specifications for systematic representation methods and project models for handling objects (such as doors, windows, walls, etc.) that make up a building between different systems. It presents the data structure and is a global standard data structure.
[0060]
  As a result, in addition to the data on columns, beams, slabs, and walls that have conventionally been linked with the structure DB-CAD, the data on the ceiling, floor, room area, and room name are collectively collected from the building DB-CAD 10 to the facility DB- It becomes possible to import to CAD11.
[0061]
  In the linkage between the structure DB-CAD 12 and the equipment DB-CAD 11, as shown in FIGS. 6 and 7, the structure DB-CAD 12 is given the chassis information to the equipment DB-CAD 11 via the structure DB converter 13, and the equipment DB-CAD 11 A diagram of a three-dimensional structure is generated in the CAD 7 for creating the facility diagram. The structure DB converter 13 plays a role of generating a structure housing on the equipment CAD.
[0062]
  Specifically, in the case of linkage of structure data to equipment (structure DB-CAD12 → equipment DB-CAD11), the structure DB converter 13 converts column / beam / slab / wall data created by the structure DB-CAD12. By doing so, it becomes possible to take in to equipment DB-CAD11.
[0063]
  The conversion work of the structure DB converter 13 will be described. (1) “Housing converter” is activated, and a drive, a directory, and a property are designated on the import property designation screen. (2) Select the target model and press the OK button. (3) Next, specify the required floor data. (4) Specify the drawing number in the drawing name specification dialog. (5) Check the specified information. After (Conversion-Drawing number-Name), drawing designation is continued, and when the designation is completed, the OK button is pushed. (6) A dialog for creating an intermediate file is displayed. When the conversion is completed, an information setting dialog is displayed. Enter the person in charge and specify where to save the converted file in the output device. Add a property code. Confirm the paper size and scale in advance with the structural designer and specify them. In the attribute conversion table, the file selection is checked and “DBCAD” is selected as the file. (8) A conversion completion display appears. (9) Since the screen returns to the initial screen, select “File”-“Exit” to end. (10) Launch Explorer. The converted data is generated under D: \ Drawfile \ Itoen \. (Extension .dwx)
[0064]
  Explaining the structure data capturing method, the structure data converted by the structure DB converter 13 is read by the facility DB-CAD 11. (1) Click the file open icon and select DWX data. In this case, a DWX drawing (* .dwx) is selected as the file type.
[0065]
  (2) When a DWX drawing to be edited is selected, a Cadwell import screen is displayed. Here, a conversion table is first selected. Table name: WELTABLE. Select wet. After selecting the conversion table, confirm that “Arrangement Layer” is set to “Architecture”, and then match “Paper Size” and “Scale”. When the setting is completed, click “OK” to open the structure diagram.
[0066]
  With the above operation, the operation for taking the data created in the structure DB-CAD 12 into the facility DB-CAD 11 is completed. This data is overlapped with the architectural drawing and the reference point. Since the structure data is not necessary when the paper is output, all the structure data is converted into auxiliary figures.
[0067]
  On the other hand, as shown in FIG. 8, sleeve equipment opening information such as a hole is returned from the equipment DB-CAD 11 to the structure DB-CAD 12 as shown in FIG. When the drawing of the facility is written in the figure of the three-dimensional structure, the opening information (sleeve information) for the pipes and ducts is returned to the structure DB-CAD 12 in the beam, the floor, and the wall, and the reinforcement of the opening is examined.
[0068]
  The other is a cross-sectional view of a steel frame called a shaft diagram in the structure DB-CAD 12, in which a sleeve is written. The information about the sleeve and opening from the equipment DB-CAD 11 can be read again on the equipment side, and the beam sleeve can be written on the axis diagram and checked.
[0069]
  More specifically describing the linkage of the sleeve / equipment opening information to the structure (equipment DB-CAD11 → structure DB-CAD12), the procedure for creating the sleeve / equipment opening information is as follows: 1) Architecture for drawing the sleeve / equipment opening 2) Layout of sleeves / equipment openings (Create a general diagram of sleeves for electricity, hygiene, and air conditioning) 3) Set drawing information (set drawing path, sleeve path, etc.) 4) Information on sleeve classification Addition (equipment category and type) 5) Sleeve / equipment opening information output (Create SL_DAT.mdb).
[0070]
  The drawing information setting method is as follows: (1) Set to air conditioning or sanitary equipment from the menu "Setting"-"Change Equipment" and start work. (2) Menu "File"-"Open" or "Open" icon Then, the drawing file for sleeve / equipment opening information output is opened, and (3) the “facility DB-CAD drawing information” dialog is displayed from the “drawing information setting” icon. (4) Specify necessary items such as “equipment DB path”, “structure DB path”, and drawing type. At this time, the drawing type is a sleeve diagram. (5) When designating “floor” and “floor order”, the user can check the floor order by referring to the structure DB by pressing the “reference structure DB” button.
[0071]
  The sleeve / equipment opening data creation method will be described. (1) A “member insertion” dialog is displayed from the menu “air conditioning” — “member” — “insert” or “device / member insert” icon. (2) Select the “Sleeve” tag, fill in the necessary items such as insert member, classification 1, and 2 and push the “OK” button. (3) Since "Please specify the insertion position (straight pipe)" is displayed in the command input bar, specify the insertion position. (4) “Specify the end point (straight pipe)” is displayed in the command input bar, so specify the end point. (5) The command input cover displays “Please determine the direction (Enter: End of selection), Shift + Left click: Change”, so determine the direction and press Enter. This inserts the sleeve. (6) Next, press the “Add sleeve section” icon. (7) The message “Please select the sleeve to which the section is to be added” is displayed. Select the sleeve and press Enter. At this time, an ID number is automatically assigned to the sleeve. (8) Since the “Equipment DB-CAD sleeve classification” dialog is displayed, the equipment classification and type of the selected sleeve are checked. In the sleeve in which the equipment category is designated, the equipment category and type are displayed as auxiliary graphic characters in the lower right as M (S).
[0072]
  (9) If you want to check for missing sleeve information, activate the check command and specify the fourth item sleeve check. After the command is executed, the information to which the sleeve classification information is not added is displayed in red. Information is added to all checked members. (10) When all drawing is completed, save the drawing. Simultaneously with the saving, the sleeve / equipment opening information is written in the database (SL_DAT.mdb) on the equipment DB path in which the sleeve information is designated.
[0073]
  The sleeve / opening information data output will be described. (1) Start up the device / equipment DB, select “Sleeve / Equipment Opening Output” from the edit menu of the target construction, and display the “Sleeve / Equipment Opening Output” dialog. (2) A dialog is displayed. Specify the data storage destination and press the “Execute” button. (3) A confirmation message is displayed. If it is OK, press the “Yes” button. (4) Since an end message is displayed, when the “OK” button is pressed, the screen returns to the edit menu screen and the output operation ends. The database file (SL_DAT.mdb) created by the above operations is read by a frame drawing CAD or a steel CAD to automatically generate subs and equipment opening information.
[0075]
  To create a shaft diagram, the sleeve / equipment opening database (SL_DAT.mdb) created by the facility DB-CAD 11 is analyzed, and the sleeve data is automatically superimposed on the shaft diagram. The method for creating a shaft diagram is as follows: (1) Open the shaft diagram created by the structure DB-CAD 12. In the structure DB, a folder structure for storing various data is organized. The data of the axis diagram is stored as DWG data in the FRAME folder under the MODEL folder. (2) Note that LAYFRM *. For the description of the contents of dwg, Drawing. It is described in mdb. (3) Drawing. Double-clicking on mdb opens a certain dialog. Open PlanFrameTbl. (4) The relationship between the DWG file name (FrameNo) of the drawing and the drawing name (how many axes are shown) can be confirmed in this table. Note that all the DWG file names in this table are described as the names of 3D data. This is replaced with the 2D data name and the drawing is selected. For example, in the figure below, the D-axis diagram is FRAME7. In this case, the data opened by the facility is LAYFRM * .dwg. dwg. (FRAME.dwg and LAYFRM * .dwg have a one-to-one correspondence.) (5) When the contents can be confirmed, the axis diagram of the target structure is opened. (6) Execute the axis drawing creation command.
[0076]
  (7) Designate a sleeve DB path and a structure DB path. 1) The sleeve DB path designates the folder set on the drawing information setting screen of the sleeve diagram. 2) The structure DB path designates the MDB folder of the structure DB converted for the sleeve diagram. Press the browse button to specify the folder, and press OK if it can be set.
[0077]
  (8) The sleeve data of each floor for the corresponding axis appears on the screen. By operating the mouse, an arrangement reference point is designated at the intersection of the FL line on the lowest floor of the axis diagram and the leftmost grid line. As a result of the above operation, the sleeve information of each floor created by the equipment DBCAD overlaps the designated axis group diagram.
[0078]
  In the procedure of facility-to-structure linkage, the data of the part passing through the frame such as a piping duct input by the facility person in charge by the facility DB-CAD is output. In this data, the position information of the location where the piping duct or the like penetrates the structural housing and the shape and size of the housing through-hole are written for the entire building.
[0079]
  When the person in charge of the structure designates the corresponding file with the “capture through-hole data import” command, the above information is described in the key frame of the structure DB-CAD, and the equipment through-hole is automatically displayed in the plan / axis diagram. Is done.
[0080]
  In the linkage between the architectural DB-CAD 10 and the structural DB-CAD 12, as shown in FIG. 9, mainly the traffic of the frame information (building shape information, building member information, building cross-section information, etc.) [the structural frame portion] "Matching" and confirming whether the body information is completely consistent with each other.
[0081]
  Even if it is referred to as a structural enclosure in both architecture and structure, there is a difference that there is a part where makeup is attached to the enclosure on the construction side compared to the enclosure on the structure side. For example, it is necessary to consider the presence of concrete that is a wall surface, the presence of finished concrete, and the fit of sashes and the like where the opening is fine, but the structure requires only large holes. Architecture is more detailed.
[0082]
  More specifically, the information of the structure DB-CAD 12 is read by the building DB-CAD 10 and superimposed on the housing itself written by the building DB-CAD 10. For example, the building itself is red, the part taken from the structure is blue, and the overlapping figure is the one superimposed on the architectural DB-CAD, including the structural information. As for the fine details, the construction is given priority, and the parts such as the finish are not related to the structural frame, so when you look at the floor part, the red part is the part where the floor finish is on It is. A thin red part appears on the surface, but there is a part of the wall concrete called “fushikashi”. This part can be checked up to a fine part, and the makeup of the building is clearly shown.
[0083]
  FIG. 11 shows that information is obtained from the construction DB-CAD 10 toward the structure DB-CAD 12 side. The red line of the composite is the core of the wall, there is a yellow wall line around it, the red part is the part that overlaps the part from the building DB-CAD10, and there are openings such as windows near C1 There is a mismatch between the architecture and the structure.
[0084]
  Basically, when there is a slight change in the size or position of the window at the stage where the design is squeezed rather than the window being inconsistent, the structure is corrected by collating it. It is a check figure when doing.
[0085]
  The three-dimensional building model input by the building staff using the building DB-CAD is output as one IFC file.
[0086]
  The person in charge of the structure takes in the information of the IFC file of the building by the “load building model” command of the structure DB-CAD. As a result, architectural member information (columns, beams, walls, wall openings, slabs, floor openings) in the building range defined by the structure DB-CAD is taken into the structure DB-CAD and the structure based on the member data of the building Drawing of each member by building information is automatically performed on each floor plan of DB-CAD. This drawing is drawn on the building data layer of each floor plan, unlike the case where the original structure DB-CAD is used for input.
[0087]
  In the conventional method, it was necessary to output the floor plan of each floor from the model input in the building as a drawing file for the number of floors and to superimpose it on the floor plan file of the structure DB-CAD for each floor. With the function, the building information for all floors of the building can be displayed in a state where only the information necessary for collation with the structural drawing is accurately overlapped with a single import instruction, greatly ensuring the work of ensuring information consistency between building structures To improve efficiency.
[0088]
  After the import is completed, the structural staff will open the floor plan of each floor, display the above drawing with the “display building material” command, and check whether there is any inconsistency with the structural member already input by the command of the structure DB-CAD. Check visually. Conventionally, information unrelated to the structure such as the wooden partition was also displayed and it took a long time to collate. However, only the structural frame in the building information was displayed by this function, and the visibility was improved.
[0089]
  If there is a contradiction between the building information and the structural information, the structural member is often modified to match the building information. Contact and discuss treatment.
[0090]
  For the wall opening, the "architecture opening information import" command was used to import the building opening information into the 3D model of the structure DB-CAD and display it as an architectural opening on the floor plan / frame diagram. If there is no problem checking the structural opening, the architectural opening is replaced with the structural opening. The replacement method can be selected individually, multiple, all, each floor, multiple floors, etc. Along with this, the wall opening of the key frame (three-dimensional model) of the structure DBCAD and the wall opening arrangement data of the housing DB are replaced and added to the wall opening cross-sectional list of the housing DB. As a result, information matching between the structural design drawing and the architectural design drawing is easily realized.
[0091]
  As an example, as shown in FIG. 26, the architecture-structure linkage system receives the MDB of the structure DB-CAD 12 from the structural designer, and selects “link / structure DB link / read structure DB” from the menu bar. .
[0092]
  Read the MDB received from the person in charge of structural design, confirm the “structure DB file” and “floor”, select the “target member” to be read, and click OK.
[0093]
  The position adjustment is performed from the respective grid information of the building and the structure, and the hatched (filled) color of the captured structural member on which the structural member is arranged is displayed in, for example, blue (pen number: 8). (See Figure 27)
[0094]
  The interference check between the structural member and the building member is as shown in FIG. 28. Select “Linkage / Structure DB Linkage / Interference Check” from the menu bar, select the check target member, and press the “Interference Check” button. As shown in FIG. 29, the building member and the structural member that interfere with the “interference member ID” and the check result are displayed.
[0095]
  As shown in FIG. 30, the structural member that interferes with the building member on the plan view is displayed in red.
  ・ When the 3D display is selected, the outline of the structural member is displayed in red.
  ・ If the opening is different (position or size), the wall where the opening exists is displayed in blue.
[0096]
  As shown in FIG. 31, when an interference member on the “interference check” screen is selected, the selected member is also selected on the plan view. “Check result” confirms the interfering part on the screen and meets with the person in charge of structural design.
[0097]
【The invention's effect】
  As described above, the integrated database CAD system of the present invention is consistent by developing the information linkage function of CAD so that information is unified and consistency can be taken naturally or the efficiency of collation work is improved. An increasing effect can be expected.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an information flow showing one embodiment of an integrated database CAD system of the present invention.
FIG. 2 is a conceptual explanatory view showing an embodiment of an integrated database CAD system of the present invention.
FIG. 3 is an explanatory diagram showing cooperation between the building DB-CAD 10 and the facility DB-CAD 11;
FIG. 4 is an explanatory diagram for checking between buildings and facilities.
FIG. 5 is an explanatory diagram of plan information / body information linkage.
FIG. 6 is an explanatory diagram showing cooperation between a structure DB-CAD 10 and an equipment DB-CAD 11;
FIG. 7 is an explanatory diagram of a structure DB converter (structure → equipment).
FIG. 8 is an explanatory diagram of cooperation (equipment → structure) of sleeve opening information.
FIG. 9 is an explanatory diagram showing cooperation between the building DB-CAD 10 and the structure DB-CAD 11;
FIG. 10 is an explanatory diagram of taking in building information (architecture → structure).
FIG. 11 is an explanatory diagram of capturing of frame information (structure → architecture).
FIG. 12 is a general view of equipment.
FIG. 13 is a diagram showing a DWG data selection screen.
FIG. 14 is a display diagram of a room area.
FIG. 15 is an explanatory diagram of a conversion table.
FIG. 16 is a screen diagram for designating a drawing.
FIG. 17 is an explanatory diagram showing reference origin / core output / adjustment.
FIG. 18 is an explanatory diagram in a case where the grids indicating the reference origin and grid output / adjustment are separated.
FIG. 19 is an explanatory diagram in a case where the relationship between the own model and the counterpart model indicating reference origin / core output / adjustment is not 1: 1;
FIG. 20 is an explanatory diagram in the case of an arc grid indicating the reference origin and grid output / adjustment.
FIG. 21 is a front view showing a screen for reading equipment members.
FIG. 22 is an explanatory diagram showing that members of the equipment DB-CAD are arranged based on an intersection of arbitrary grids.
FIG. 23 is a front view showing a screen for checking interference between equipment members and building members.
FIG. 24 is an explanatory diagram showing an interference relationship between equipment members and building members.
FIG. 25 is an explanatory diagram of interference display.
FIG. 26 is a front view showing a structural member reading screen;
FIG. 27 is an explanatory view showing a state where the building and the structure are overlapped and a display of only the read structural member.
FIG. 28 is a front view showing a screen for checking interference between a structural member and a building member.
FIG. 29 is an operation explanatory diagram of an interference check between a structural member and a building member.
FIG. 30 is an explanatory diagram showing a display of an interference situation.
FIG. 31 is an explanatory diagram of interference member selection on the interference check screen.
FIG. 32 is an explanatory diagram of an architectural 3D-CAD system.
FIG. 33 is an explanatory diagram of an equipment DB-CAD system.
FIG. 34 is an explanatory diagram of a structural DB-CAD system.
[Explanation of symbols]
  1 ... Architectural 3D-CAD 2 ... Original DB
  3 ... Related systems 4, 5 ... Interface
  6 ... CAD for equipment drawing 7 ... PC
  8 ... Structure DB-CAD 10 ... Architecture DB-CAD
  11 ... Equipment DB-CAD 12 ... Structure DB-CAD
  13. Structure DB converter

Claims (1)

Is a CAD shea scan Temu on a personal computer,
Architectural DB-CAD consisting of a combination of architectural 3D-CAD system and DB (database) that can use commercially available 3D-CAD software as it is for finishing, joinery, etc.,
Equipment DB-CAD consisting of a combination of a personal computer with a built-in CAD software for creating equipment diagrams and a DB (database) for equipment / equipment, piping, ducts, wiring, etc .;
Concerning pillars, beams, slabs, etc., it consists of three DB-CADs, a structure DB-CAD that functions as a drawing CAD on the one hand, and links to a DB (database) on the other hand, centering on a 3D building model. in the database CAD system,
Equipment DB-CAD gives equipment 3D information (three-dimensional information of equipment) to construction DB-CAD, and equipment DB, and equipment DB-CAD gives equipment members, columns, beams, walls, ceilings, etc. Return 3D interference information with building materials, and plan information (plan view, room area, room name, ceiling height, floor height), building shape information, building member information, building cross-section information, etc. Information transportation means between the building DB-CAD and the equipment DB-CAD, which gives frame information;
Position information for building structure information such as building shape information, building member information, and building cross-section information is given from structure DB-CAD to equipment DB-CAD, and a hole is drilled from structure DB-CAD to structure DB-CAD. Information return means between the structure DB-CAD and the equipment DB-CAD, which returns the information on the opening of the housing (sleeve), etc.
Between the building DB-CAD and the structure DB-CAD, there is provided an information passing means between the building DB-CAD and the structure DB-CAD for transferring building information such as building shape information, building member information, building cross-section information,
In the architecture DB-CAD,
Means for automatically determining interference between equipment members and building members taken from equipment DB-CAD;
There is provided means for superimposing and displaying the frame information taken from the structure DB-CAD and the frame information created by the architecture DB-CAD,
In the structure DB-CAD,
An integrated database CAD system characterized by comprising means for superimposing and displaying the frame information taken from the architectural DB-CAD and the frame information created by the structure DB-CAD .

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