JP2017224014A - Processing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve labor saving and quickness and also improve processing capacity.SOLUTION: A processing system uses a virtual three-dimensional model of an aggregate of individual components forming a building. Attribute information and an identifier of a configuration space are added to data of the configuration space, and attribute information and an identifier of a component are added to data of the component. The processing system comprises a database unit including: a storage database unit which stores attribution data indicating a correspondence among the data of the configuration space, data of the component, and identifiers of the configuration space and the component in a tabular format, and which is capable of reading and writing data in a bi-directional manner from/to the virtual three-dimensional model; and a processing database unit for performing arithmetic processing of each piece of data in the storage database unit. The system performs data substitution in a bi-directional manner between the database unit and the virtual three-dimensional model. The processing database unit refers to the attribution data and associates data of the configuration space with data of the component belonging to the configuration space.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a processing system.

  Conventionally, when totaling the parts that make up a building, the number of parts (for example, wall size, floor area, etc.) from the drawing of the design book (specification, plan, elevation, cross-section) ) And manually entering it into the integration software. And the cost information (unit price etc.) was added to the integration result, and it detailed.

  There has also been proposed a system that automatically performs processing such as estimation in building construction by using CAD data (see, for example, Patent Document 1).

JP 2009-145983 A

  There is a problem that the work of picking up the quantity from the drawing or manually inputting it into the integrating software or another numerical calculation (for example, heat load calculation) software is labor intensive and takes time. Furthermore, in the system of Patent Document 1, the flow of processing is unidirectional, and complicated processing that straddles classifications (categories) according to the contents of parts cannot be performed.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to save labor and speed and to improve processing capability.

In order to achieve such an object, a processing system of the present invention is a processing system using a virtual three-dimensional model of an assembly of parts constituting a building, and the data of the configuration space constituting the space in the building is used. The attribute information and identifier of the component space are added, and the attribute information and identifier of the component part are added to the data of the component component other than the component space among the components, and the component space data, A storage database in which component data and affiliation data indicating the correspondence between the configuration space identifiers and the component component identifiers are stored in a tabular format, and the virtual three-dimensional model can be read and written bidirectionally. And a database unit having a processing database unit that performs arithmetic processing on each data of the storage database unit, the database unit and the virtual 3 The system performs bidirectional data replacement with an original model, and the processing database unit refers to the affiliation data and associates the data of the configuration space with the data of the component parts belonging to the configuration space It is characterized by doing.
According to such a processing system, it is possible to save labor and speed and to improve processing capability.

In this processing system, it is preferable that the processing database unit sorts the component parts for each specific attribute information and acquires the quantity.
According to such a processing system, it is possible to easily perform aggregation for each specific attribute information.

In this processing system, the processing database unit performs arithmetic processing on a part that does not exist in the virtual three-dimensional model using at least one of the attribute information of the configuration space or the attribute information of the component part, It is desirable to get
According to such a processing system, a component that does not exist in the virtual three-dimensional model can be calculated by an arithmetic operation.

In this processing system, it is preferable that the processing database unit lists the component parts belonging to the configuration space.
According to such a processing system, it is possible to easily grasp the component parts belonging to the configuration space.

In this processing system, it is preferable that the processing database performs addition / subtraction processing of calculation results based on attribute information of the component and attribute information of the configuration space to which the component belongs.
According to such a processing system, it is possible to calculate a quantity (for example, a finished area of the configuration space) that cannot be calculated only by the attribute information of the component parts or the attribute information of the configuration space.

In this processing system, the database unit further includes a unit price database unit that stores a unit price of each part, and the processing database unit multiplies the calculation result of the quantity of each part by the unit price of each part. It is desirable to calculate the estimated amount together.
According to such a processing system, it is possible to easily estimate each component.

In this processing system, it is preferable that the processing database unit converts the calculation result into a form format for each configuration space and outputs the result.
According to such a processing system, it is possible to deal with sheet-like (form form) output.

In this processing system, it is preferable that the processing database unit performs a calculation related to a predetermined component arranged in the configuration space based on attribute information of the configuration space.
According to such a processing system, a predetermined component suitable for the configuration space can be obtained.

In this processing system, it is preferable to include a processing unit that places the predetermined component corresponding to the calculation result in the configuration space of the virtual three-dimensional model.
According to such a processing system, a predetermined component can be automatically written in the virtual three-dimensional model.

  According to the present invention, it is possible to save labor and speed, and improve processing capability.

It is explanatory drawing which shows the outline | summary of the processing system of 1st Embodiment. It is a figure which shows an example of a room table. It is a figure which shows an example of a belonging table. It is a conceptual diagram which shows the process of 40 A of 1st process database parts. It is a figure which shows the specific process flow of 40 A of 1st process database parts. It is a figure which shows the output layout of a form format. It is a figure which shows the output layout of a form format. It is a figure which shows the output layout of a form format. It is a conceptual diagram which shows the process which 40 A of 1st process database parts of 2nd Embodiment perform. It is a figure which shows the output of the 2nd process database part 40B of 2nd Embodiment. It is a figure which shows the information of a power distribution system.

=== BIM Overview ===
First, an outline of BIM, which is the basis for describing the present invention, will be briefly described.

  In the past, the number of parts (for example, wall size, floor area, etc.) was picked up manually from the drawing of the design book (specification, plan, elevation, cross section) and entered manually into the integration software. . Then, cost information (unit price, etc.) is added to the result of integration, and specification (estimate creation, etc.) is performed. For example, the specification information is created by confirming the form information based on the drawing, and the integration / estimation is performed from the drawing / specification. For this reason, a certain amount of work time is required in each process, and a corresponding period is required until an estimate is completed.

  Therefore, a system has been developed that automatically performs processing such as estimation in building construction by a computer by using CAD data.

  BIM (Building Information Modeling) is a virtual three-dimensional (3D) model of a building created on a computer, and is a model of an assembly of parts constituting the building. In the BIM model, attribute information including a form (shape / position), a quantity such as an area calculated from the form, and specifications is added to each part constituting the building. For example, for a wall of a building, attribute information such as information “wall”, shape information including size / thickness, etc., name (model number) of the wall, and specification information is added and registered in a computer database. In the BIM model, a room constituting a building space is also handled as a part, and room attribute information is added to the room data.

  Using such a BIM model, it is possible to perform technical studies such as building design. However, in the BIM model, attribute information for each category (room, door, window ...) can be displayed and tabulated in a tabular format, but relevance across categories could not be connected. . For example, since which room a door belongs to is managed as door information, the door belonging to the room cannot be displayed in the room summary table. In the present embodiment, the BIM model is used to save labor and speed, and the BIM model improves processing capability.

=== First Embodiment ===
<About system configuration>
FIG. 1 is an explanatory diagram illustrating an overview of a processing system according to the first embodiment.

  As shown in FIG. 1, the processing system of this embodiment is a system having a BIM model 10 and a database unit 20.

  The database unit 20 includes a storage database unit 30, a processing database unit 40, and a unit price database unit 50. Further, the processing database unit 40 includes a first processing database unit 40A and a second processing database unit 40B. Yes.

  Each of these units is realized by a storage unit or a calculation unit (CPU) of a computer, and the BIM model 10 and the storage database unit 30 are configured by software functions of the BIM model 10. In addition, the computer includes an input unit (such as a keyboard and a mouse) for inputting data and a display unit (such as a display) for outputting calculation results. 1 may be provided in a single computer, or each unit may be provided in a separate computer and connected via a communication line or the like.

  As described above, the BIM model 10 is a virtual three-dimensional model of a building. Although one room is illustrated as the BIM model 10 in FIG. 1, a plurality of spaces such as rooms and corridors are provided in the building of the BIM model 10 of the present embodiment.

  In each part of the building of the BIM model 10 of the present embodiment, a component space (for example, a room, a corridor, etc.) that constitutes the space, and a component other than the component space (for example, a door, a window, a wall, etc.) Furniture, appliances, etc.). A category is prepared for each part (configuration space and component) of the building, and each part has a category in the attribute information. For example, the door attribute information includes information indicating a door category. The boundary of the configuration space is formed by walls (components), and doors and windows can be arranged with respect to the walls.

  The storage database unit 30 stores the data of each part of the building of the BIM model 10 for each part category and stores it in a tabular table. The storage database unit 30 is linked to the BIM model 10 and can read and write data in both directions. As a result, the BIM model 10 and the database unit 20 can exchange data (data replacement) in both directions. That is, when the content of the BIM model 10 is changed, the data in the storage database unit 30 is changed accordingly, and when the data in the storage database unit 30 is changed, the BIM model 10 is changed accordingly.

  The processing database unit 40 includes a first processing database unit 40A and a second processing database unit 40B.

  40 A of 1st process database parts perform various arithmetic processing using the data of the storage database part 30, and the data of the unit price database part 50 (after-mentioned). The first processing database unit 40A incorporates various calculation formulas that perform appropriate calculations using information on the form (quantity, dimensions, area, etc.) and information on specifications (finishing, etc.) among the attribute information of each data. It is. In addition, the first processing database unit 40A can change the data in the storage database unit 30.

  The second processing database unit 40B outputs the calculation result of the first processing database unit 40A in a form format (room information sheet described later) for each configuration space. When the contents of the form are changed, the second processing database unit 40B changes the data in the direct storage database unit 30 via the first processing database unit 40A.

  In the unit price database unit 50, the unit price of each element (component) constituting the building of the BIM model 10 is stored in a table format in association with each element.

  Further, the processing system of the present embodiment includes a program 60 (corresponding to a processing unit) that selects parts based on the calculation result of the first processing database unit 40A of the database 20 and automatically places them in the BIM model 10. The program 60 will be described later.

<About data in the storage database unit 30>
Next, data in the storage database unit 30 will be described.

  As described above, each data of the BIM model 10 is stored in the storage database unit 30 in a table for each category. For example, as shown in FIG. 1, tables such as a room table, a door table, a window table, an belonging table, etc. are stored in a table format. The room table corresponds to the data of the configuration space, the table of parts (doors, windows, walls, etc.) other than the room corresponds to the data of the component parts, and the belonging table corresponds to the belonging data.

  FIG. 2 is a diagram illustrating an example of a room table. As shown in the figure, the room table of the BIM model 10 includes an ID (corresponding to an identifier) assigned to each room, and information (attributes) such as the room circumference, area, room name, ceiling height, and finish. Equivalent to information). Among these, the perimeter and area are automatically calculated on the model, and the ceiling height (room height) and finishing information are manually input. This input can be performed from either the BIM model software or the database software. Moreover, other information (for example, the volume of a room) can also be automatically calculated using these values (attribute information).

  Similarly, a table of each element (component) such as a door, a window, and a wall is added with attribute information (form, quantity, etc.) and ID for each element. For example, the door table includes each information such as an ID assigned to each door and the type, specification, quantity (dimension) of the door.

  FIG. 3 is a diagram showing an example of the belonging object table. This belonging table shows the correspondence between room IDs and element IDs, regardless of the category of elements (components), and is stored in a table format as shown in the figure.

<About the process of the first process database unit 40A>
FIG. 4 is a conceptual diagram showing an example of processing of the first processing database unit 40A. The query shown in the figure is a function of database software for processing information in a table.

  When processing a room, the first processing database unit 40A refers to the belonging table and associates (associates) the room table with the table of each element. This process is executed for each element category. In this way, the first processing database unit 40A aggregates the parts belonging to the room and creates a new list (a list for the room). Thereby, it is possible to easily recognize parts belonging to the room. Then, the first processing database unit 40A performs arithmetic processing on the room using this data.

  FIG. 5 is a diagram illustrating an example of a specific processing flow of the first processing database unit 40A.

  As described above, attribute information such as ID, area, circumference, ceiling height, and finishing information is added to the room table. The first processing database unit 40A refers to the belonging table, and associates the room table with a table of components (here, doors) belonging to the room. Moreover, although not shown in figure, similarly, it matches similarly about the wall and window arrange | positioned in a room.

  Then, the first processing database unit 40A performs various arithmetic processes. For example, as shown in FIG. 5, the first processing database unit 40A calculates the wall area by multiplying the circumference of the attribute information of the room table and the ceiling height. Further, the area of the door arranged in the room is acquired from the attribute information of the door table, and the area of the door is subtracted from the wall area. For example, when a window is provided in the room, the area of the window is similarly subtracted. Thus, the wall finishing area is calculated. As a result, it is possible to calculate the quantity (here, the wall finishing area) that cannot be calculated only with the attribute information of the room table or the attribute information of the room table. In addition, although the case where subtraction was required was demonstrated here, when addition is required, you may perform an addition process.

  Further, the first processing database unit 40A also calculates the number of parts that do not exist in the category of the BIM model 10. For example, the skirting board does not exist in the category of the BIM model 10, but the first processing database unit 40A includes the attribute information (perimeter) of the room table and the attribute information (door) of the door table of the door arranged in the room. The width of the baseboard is calculated by subtracting the door width from the perimeter of the room. In this way, parts that do not exist in the category of the BIM model 10 can be calculated by the arithmetic processing.

  In addition, the first processing database unit 40A sorts the calculated quantity for each specific attribute information. For example, when material and strength are included as attribute information, parts are sorted for each material (or for each strength), and the quantity is calculated. As a result, it is possible to facilitate the aggregation for each specific attribute information.

  Furthermore, the first processing database unit 40A multiplies the calculated quantity of each part by the unit price set in the unit price database unit 50 to calculate an estimated amount for each part. For example, the unit price associated with the floor finish of the attribute information of the room table is acquired from the unit price database unit 50, and the floor area calculated in FIG. 5 is multiplied by the unit price to calculate the estimated floor finish amount (see FIG. 6C). Similarly, an estimated amount of baseboard is calculated by multiplying the baseboard length calculated in FIG. 5 by a baseboard unit price, and multiplying a wall finishing area by a wall finishing unit price to calculate an estimated wall finish amount. Thereby, estimation for every component can be performed easily.

  Furthermore, the first processing database unit 40A calculates the estimated amount for the room by summing up the estimates of the parts. In this embodiment, the estimated amount of the part for each room is calculated. However, the floor of the building may be regarded as one space, and the sum may be calculated for each part floor. Further, the total estimated amount of parts may be calculated by regarding the entire building as one space. Thus, it is good to calculate by a method suitable for each category of parts. For example, since the floor is formed over a plurality of rooms, it is desirable to aggregate the materials (concrete etc.) constituting the floor for each floor. On the other hand, the floor finish varies from room to room, so it is desirable to add up for each room.

<Processing of Second Processing Database Unit 40B>
As described above, the second processing database unit 40B outputs the calculation result of the first processing database unit 40A in a form format layout. Thereby, in this embodiment, it can respond to the output of a sheet form (form form). Here, the display (output) is performed on a computer display, but the present invention is not limited to this. For example, printing may be performed on a medium such as paper using a printer.

  6A to 6C are diagrams illustrating an example of an output layout in a form format by the second processing database unit 40B. As shown in FIGS. 6A to 6C, the second processing database unit 40B edits the calculation results of the room table (including attribute information) and the first processing database unit 40A into a form as shown in FIGS. 6A to 6C. Output.

  The sheet in FIG. 6A describes the room attribute information (summary / specification / finishing information) obtained from the room table, and the parts (doors, etc.) belonging to the room are aggregated as belongings. It is described. That is, since the correspondence between the room data and the element (parts) data is taken in the belonging table, the parts belonging to the room can be grasped.

  In the sheet of FIG. 6B, a room quantity table (perimeter, ceiling height, etc.) is described. Here, the attribute information (length, area) of the room, the attribute information (length. Area) of the door arranged in the room, and the wall finish area calculated using these attribute information, The length of the skirting board, the floor finishing area, and the ceiling finishing area (see FIG. 5) are described.

  In the sheet of FIG. 6C, an estimated amount obtained by multiplying the unit price and quantity for each part / finish is described. For example, for the finishing of the top board, the finishing material, the unit price, the top board finishing area, and the estimated amount calculated by multiplying the finishing unit price and the finishing area are described. Then, all the estimated amounts calculated for each part are added, and the room finishing total (estimated amount for finishing the room) is described.

  In the present embodiment, as shown in FIGS. 6A to 6C, the output is in the form format, but the present invention is not limited to this, and the output may be in the form of a single form.

  In the present embodiment, as described above, since the BIM model 10 and the database unit 20 can exchange data in both directions, the contents (data) of the form output in FIGS. 6A to 6C can be changed to change the BIM model 10. And the estimate can be processed immediately. For example, the process of changing each data of the BIM model 10 according to the customer's request and recreating the estimate can be easily and quickly performed.

  As described above, since the BIM model 10 is used in the present embodiment, it is possible to save labor and speed compared to the case where the number of parts is aggregated or estimated using a drawing. Further, in the processing system of the present embodiment, the first processing database unit 40A refers to the belonging table and associates the room table with the table of each element (component), so that it crosses the categories. Complicated processing can be performed. Thereby, data arrangement and editing based on the room can be performed, and it is possible to grasp what parts are arranged in the room.

=== Second Embodiment ===
In the second embodiment, by inputting equipment conditions into the BIM model, for example, numerical calculation (ventilation calculation / heat load calculation) necessary for air conditioning equipment design is performed, and the components to be installed are set. And different. Since the basic configuration is the same as in FIG. 1, the following description will be made using the same reference numerals as in FIG.

  FIG. 7 is a conceptual diagram illustrating an example of processing performed by the first processing database unit 40A of the second embodiment.

  As shown in FIG. 7, the room table of the second embodiment includes volume, number of persons (capacity of persons), and ventilation method as attribute information.

  The first processing database unit 40A of the second embodiment calculates the thermal load of the room from the room table, belonging table, and window table. Note that, as described in the first embodiment, all elements (components) can be organized and edited from the relationship with the room (configuration space), so that it is possible to perform calculation processing across the categories of elements. For example, since the heat load is related to the length of the outer wall of the room, the number of windows and the direction, the calculation of the heat load is also performed using the attribute information of the walls constituting the room and the attribute information of the windows. Do.

  Then, the calculation result of the heat load is returned to the BIM model 10 and the air conditioner corresponding to the heat load is automatically selected by the program 60 for automatically selecting the air conditioner (corresponding to a predetermined component) from the result ( Place it in the corresponding room). This result is stored again in the storage database unit 30, and the first processing database unit 40A can organize and edit the data based on the room as in the first embodiment.

  FIG. 8 is a diagram illustrating an example of the output of the second processing database unit 40B of the second embodiment.

  The facility design condition item can be input from either the BIM model software or the database software. With this setting, load calculation is executed as shown in FIG. 7, and the value is displayed in the output (form form) of the second processing database unit 40B. For example, in FIG. 8, the total heat load is about 2175 W, and an air conditioner with a cooling capacity of 2.2 kW is selected by the processing of the program 60 described above, and the air conditioner is automatically applied to the BIM model 10. Be placed.

  Moreover, basic information on the electrical equipment design of the building can be acquired from the load calculation result. FIG. 9 is a diagram illustrating an example of information on the distribution system.

  The processing database unit 40 of the second embodiment can create a distribution board list as shown in FIG. 9 by automatically arranging air conditioners from load calculations and counting the quantities. In addition, the power panel list can be created by determining the outdoor unit corresponding to the air conditioner.

  In the present embodiment, the heat load is calculated, but the present invention is not limited to this. For example, PAL calculation may be performed.

  Moreover, in this embodiment, although the air conditioner was automatically arrange | positioned according to a room, it is not restricted to this. For example, a lighting device suitable for a room may be automatically arranged. In this case, the attribute information of each element (component) may not be used as long as it is possible to set the type and quantity of the luminaire using only the room attribute information (for example, the ceiling area).

=== Other Embodiments ===
The above embodiment is for facilitating the understanding of the present invention, and is not intended to limit the present invention. The present invention can be changed and improved without departing from the gist thereof, and it is needless to say that the present invention includes equivalents thereof. In particular, the embodiments described below are also included in the present invention.

<About the system>
In the above-described embodiment, a case has been described in which the BIM model 10 is used to calculate the integrated estimate, design, and form. A processing system of a form may be applied.

<About the processing database unit 40>
In the above-described embodiment, the processing database unit 40 includes the first processing database unit 40A and the second processing database unit 40B. However, these functions may be performed by one processing database unit.

  In the above-described embodiment, the number of baseboards is calculated as a part that does not exist in the BIM model 10, but the present invention is not limited to this. For example, the coating amount may be calculated. In the above-described embodiment, both the room attribute information and the part (door) attribute information are used when calculating a part that does not exist in the BIM model 10. You may calculate using.

10 BIM Model 20 Database Unit 30 Storage Database Unit 40 Processing Database Unit 40A First Processing Database Unit 40B Second Processing Database Unit 50 Unit Price Database Unit 60 Program

Claims (9)

A processing system using a virtual three-dimensional model of an assembly of parts constituting a building,
The attribute information and identifier of the component space are added to the data of the component space constituting the space in the building, and the attribute information and identifier of the component part are included in the data of the component components other than the component space among the components. Is added,
The configuration space data, the component data, and affiliation data indicating the correspondence between the configuration space identifiers and the component identifiers are stored in a tabular format and interactively with the virtual three-dimensional model. A storage database section that can read and write data;
A processing database unit for computing each data of the storage database unit;
Including a database unit, and performing bidirectional data replacement between the database unit and the virtual three-dimensional model,
The processing database unit refers to the affiliation data and associates the data of the configuration space with the data of the component parts belonging to the configuration space.
A processing system characterized by that. The processing system according to claim 1,
The processing system is characterized in that the processing database unit sorts the component parts for each specific attribute information and acquires the quantity. The processing system according to claim 1 or 2,
The processing database unit obtains a quantity by performing arithmetic processing on a component that does not exist in the virtual three-dimensional model using at least one of the attribute information of the configuration space or the attribute information of the component. Processing system. A processing system according to any one of claims 1 to 3,
The processing database unit lists the component parts belonging to the configuration space. A processing system according to any one of claims 1 to 4,
The processing database performs an addition / subtraction process of calculation results based on attribute information of the component and attribute information of the configuration space to which the component belongs. A processing system according to any one of claims 1 to 5,
The database unit further includes a unit price database unit for storing a unit price of each component,
The processing database unit calculates an estimated amount by multiplying a calculation result of the quantity of each component and a unit price of each component. A processing system according to any one of claims 1 to 6,
The processing database unit converts a calculation result into a form format for each configuration space and outputs the result. A processing system according to any one of claims 1 to 7,
The processing database unit performs a calculation related to a predetermined component arranged in the configuration space based on the attribute information of the configuration space.
A processing system characterized by that. The processing system according to claim 8,
A processing unit that arranges the predetermined component according to the calculation result in the configuration space of the virtual three-dimensional model;
A processing system characterized by that.