KR101916358B1 - Automatic modeling system of concrete form using stock information - Google Patents

Abstract

The present invention relates to a formwork panel automatic modeling system using inventory information that maximizes the utilization rate of a form panel by preferentially reflecting stock quantity of the formwork panel in an automatic modeling process for designing a form panel.
The present invention relates to automatic designing of a formwork panel for constructing a reinforced concrete structure, comprising: tag means for attaching to an existing formwork panel and storing an identification code; Recognition means for recognizing information of the tag means; Inventory information processing means for receiving the information recognized by the recognizing means and sorting the form panels held by each type and storing the quantity information for each classification; A form modeling means for modeling and matching the form panel to the member shape information; The form modeling means reflects the information of the formwork panels of the inventory information processing means to perform the form-only designing primarily by matching the moldable panels that are available and can match the formwork panels The automatic design of the formwork panel is performed by performing the remaining design by the second order by matching the new formwork panels.

Description

Technical Field [0001] The present invention relates to an automatic modeling system for a form panel using stock information,

The present invention relates to a formwork panel automatic modeling system using inventory information that maximizes the utilization rate of a form panel by preferentially reflecting stock quantity of the formwork panel in an automatic modeling process for designing a form panel.

In recent years, various automation design techniques have been introduced and used to increase the work efficiency of practitioners in construction and civil works. Techniques related to automatic design of formwork panels for improving the work efficiency of formwork construction have also been developed and used.

On the other hand, conventional formwork design was performed by comparing the formwork panel design information calculated at the time of formwork panel design and the current formwork form.

As a result, the design of the formwork panel is carried out separately without consideration of the moldable panel. Therefore, the exclusive use rate of the formwork panel is not utilized properly. As a result, the increase in the quantity of the new formwork panel is uneconomical.

In addition, in the conventional form panel automatic design method, the 2D shape information is extracted from the 3D shape information of the structure on the basis of the surface of the member, and the form is placed on each surface (Patent No. 10-1732314, etc.).

However, if the model is directly matched to the 2D surface of each member as described above, the amount of information to be processed increases, and the processing speed is lowered.

Also, members such as walls, columns, and beams are arranged such that a pair of dies face each other. Therefore, it is troublesome to model one side mold first and then separately model the other side mold in order to install attachments attached to a connection object or other form such as foam tie or the like. In this process, the position information of the attached objects such as the connection objects and the attachments, which are modeled in this process, is often inconsistent with the modeled panel. If such a design error is found, the entire time must be remodeled, have. In addition, there is no information about the thickness of the member, so that it is inconvenient to manually input the specification of the connection object such as form tie or the setting of the notch position.

In addition, since the existing model is modeled by filling a form on the 2D face of the member, it is difficult to completely re-model the form panel of the member face when the 2D shape information is changed due to the design change.

In order to solve the above problems, the present invention provides an automatic modeling process for designing a formwork panel, comprising the steps of: To provide an automatic modeling system.

The present invention provides a formwork panel automatic modeling system using inventory information that can shorten the work time by minimizing the information throughput for designing a form panel by matching and modeling the form with the member sectional information extracted from the 3D form information .

An object of the present invention is to provide a formwork panel automatic modeling system using inventory information which can easily match an attached object such as a form tie or the like attached to other formworks and minimize a design error.

An object of the present invention is to provide an automatic modeling system for a form panel using inventory information that can easily modify related information even when a design is changed.

According to a preferred embodiment of the present invention, there is provided a method of automatically designing a form panel for constructing a reinforced concrete structure, the method comprising: tag means for attaching to an existing formwork panel and storing an identification code; Recognition means for recognizing information of the tag means; Inventory information processing means for receiving the information recognized by the recognizing means and sorting the form panels held by each type and storing the quantity information for each classification; A form modeling means for modeling and matching the form panel to the member shape information; The form modeling means reflects the information of the formwork panels of the inventory information processing means to perform the form-only designing primarily by matching the moldable panels that are available and can match the formwork panels And automatically designing the form panel by performing the remaining design by performing the second-order design by matching the new form panels.

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According to another preferred embodiment of the present invention, the inventory information processing means stores the form panel history information, and provides the automatic formwork panel modeling system using stock information.

According to another preferred embodiment of the present invention, the tag means is a barcode or a QR code imprinted on the rear surface of the formwork panel.

According to another preferred embodiment of the present invention, the form modeling means includes a 3D modeling module for generating 3D shape information of a structure; A sectional information output module outputting sectional shape information from the 3D shape information generated from the 3D modeling module; A matching information generation module for modeling the form panel on the sectional shape information output from the sectional information output module to generate the form matching information; A display module for outputting and displaying the die matching information; The present invention provides an automatic modeling system for a form panel using stock information.

The present invention has the following effects.

First, in the automatic modeling process for designing the form panel, automatic design of the form panel is performed in the form modeling means by reflecting the state of the form panel during the retention stored in the inventory information processing means. Therefore, it is possible to prioritize the inventory quantity of the retained formwork panel, thereby maximizing the exclusive use rate of the formwork panel, thereby enabling economical construction.

Second, when designing form panels such as alfons and steel foams, modeling is performed by matching the form with the sectional shape information extracted from the 3D shape information of each member of the structure, thereby minimizing the information processing amount for designing the form panel, can do.

Third, since the connection object installation information for connecting the form panel in advance according to the cross-sectional type and the attachment installation information attached to the form are provided in the matching DB in advance, matching of the connection object or attachment installation information such as form ties is easy, Thereby minimizing design errors.

Fourth, because the user can change the cross-sectional shape information, the modification of the related information can be made very simply by changing the absence information at the time of design change. Therefore, it is convenient to design and change form panels easily.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a formwork panel automatic modeling system using stock information of the present invention; FIG.
2 is a diagram showing a design execution sequence of the form modeling means;
3 is a perspective view showing the tag means provided on the form panel;
4 is a flowchart of an automatic modeling method of a form panel.
5 is a diagram showing a member information management window among 2D sectional shape information output from 3D shape information.
6 is a 2D view for outputting form matching information;
7 is a view showing a 3D view for outputting form matching information;
8 is a diagram showing die matching information output from a 2D view or a 3D view;
9 is a flowchart showing a method of generating workpiece matching information through a matching DB;
10 is a view showing an attachment information management window among 2D sectional shape information output from 3D shape information;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1 is a configuration diagram of a form panel automatic modeling system using stock information of the present invention.

As shown in FIG. 1, a formwork panel automatic modeling system using inventory information according to the present invention is for automatically designing a formwork panel for constructing a reinforced concrete structure. The formwork panel is attached to the formwork panel 1, Stored tag means (2); Recognition means (3) for recognizing information of the tag means (2); Inventory information processing means (4) for receiving the information recognized by the recognition means (3), sorting the form panels (1) held by the form, and storing the quantity information for each classification; A form modeling means 5 for modeling and matching the form panel 1 to the member shape information; Wherein the form modeling means 5 performs automatic design of the formwork panel 1 by reflecting information of the formwork panel of the stock information processing means 4. [

The automatic modeling of the formwork panel (1) for constructing the reinforced concrete structure is carried out by firstly reflecting the stock quantity of the retained formwork panel in the process of automatic modeling of the formwork panel System.

The tag means (2) is attached to the formwork panel (1) being held and an identification code is stored.

The tag means (2) is attachable to the rear surface of each formwork panel (1).

The tag means 2 may be a bar code, a QR code, an RFID chip, or the like.

The recognition means (3) recognizes the information of the tag means (2).

The recognition means 3 recognizes the tag means 2 such as a bar code, a QR code, and an RFID chip and receives identification code information.

Recognizes the identification code of the form panel (1) currently held by the recognition means (3) and transmits it to the inventory information processing means (4).

The inventory information processing means 4 receives the information recognized by the recognition means 3 and classifies and stores the current state of the formwork panel 1 being held.

The inventory information processing means 4 classifies the collected form panels by type and stores the quantity information for each classification.

The form modeling means 5 matches the form panel 1 with the member shape information and models it.

At this time, the form modeling means 5 performs automatic design of the formwork panel 1 by reflecting the information of the formwork panel of the stock information processing means 4. [

The form modeling means 5 is configured to automatically design the formwork panel 1 by matching the form to the shape information of the member. The formwork modeling means 5 reflects the state of the formwork panel input by the stock information processing means 4, The panel 1 is used to design it.

The inventory information processing means 4 receives and stores the stored formwork panel information matched by the formwork modeling means 5, thereby making it possible to utilize not only the formwork panel information but also the expected demand and production plan of the formwork panel 1 .

Fig. 2 is a diagram showing a design execution sequence of the form modeling means.

As shown in FIG. 2, the form modeling means 5 reflects the stored form panel information of the stock information processing means 4 and performs a form-only design primarily by matching the mold panels which can be held And then perform the remaining design of the mold panel 1 by matching the parts of the mold panel which can not be matched by the new mold panels.

That is, the form modeling unit 5 can automatically design by first performing dedicated design using all of the die-cutable panels 1, and then matching the new die plates only to the remaining parts.

As a result, it is possible to utilize the existing form panels as a maximum exclusive rate.

Then, the amount of new mold panel production is calculated by matching new mold panels through the second residual design.

The inventory information processing means 4 may be configured to store the form panel history information.

As the number of times of exclusive use of the form panel 1 increases, the material life is shortened.

Therefore, the history information such as the number of times of exclusive use, the estimated remaining life or the number of estimated remaining remainders is inputted to the stock information processing means 4 for each form panel 1 and stored, thereby enabling more accurate material procurement plan establishment, The final frame quality can be improved.

In addition, when the number of times of laying of the formwork panel being held exceeds the preset limit number of times, it can be automatically excluded from the formwork panel information outputted to the form modeling means 5.

3 is a perspective view showing the tag means provided on the form panel.

As shown in FIG. 3, the tag means 2 may be formed of a bar code or a QR code imprinted on the rear surface of the formwork panel 1. [

Since the form panel 1 is exposed to an external impact during construction and needs to be cleaned after use, the tag means 2 may be detached from the form panel 1 during this process.

Therefore, the bar code or the QR code is engraved on the rear surface of the form panel 1 by being embossed or embossed so as to be unified, thereby preventing the tag means 2 from falling off during the construction, washing or storage of the formwork panel 1.

4 is a flowchart of an automatic modeling method of a form panel.

As shown in FIG. 1, the form modeling means 5 includes a 3D modeling module 51 for generating 3D shape information of a structure; A sectional information output module 52 for outputting sectional shape information from the 3D shape information generated from the 3D modeling module 51; A matching information generating module 53 for modeling the form panel to the sectional shape information outputted from the sectional information output module 52 to generate the form matching information; A display module 54 for outputting and displaying the die matching information; .

Accordingly, the form panel automatic modeling system using the inventory information of the present invention can automatically model the form panel through the process as shown in FIG.

The present invention is applicable to a wall, a column, a beam, and the like in which a form panel is installed on both sides of a member.

In this case, by matching the form with the mold section information extracted from the 3D shape information of each member constituting the structure, the amount of information to be processed can be minimized and the working time can be shortened.

The 3D modeling module 51 generates 3D shape information of the structure.

The 3D shape information may be stored as BIM digital data.

The cross-sectional information output module 52 outputs cross-sectional shape information from the 3D shape information generated from the 3D modeling module 51.

The section information output module 52 first selects a member to output the cross-sectional shape information. Then, the 2D sectional shape information of the member is outputted from the 3D shape information of each member. At this time, the cross-sectional shape information is output for each position where the cross-sectional shape is changed in one member.

The information on the connecting member on the surface where the cross-section (or elevation) is generated as geometrical information is automatically output to the cross-sectional shape information. That is, for a wall (or beam), the level and shape information of a member such as a beam, a sled or other wall connected at both a hemisphere (elevation) and a side (detail view) is automatically calculated. In the case of a column Level and shape information of members such as slabs or walls connected to each other on the elevation plane are automatically calculated. If the calculated results are the same, this information is integrated so that the user can obtain common cross-sectional shape information on the elevation Only the information about it is output. Thereby minimizing the cross-sectional shape information to be designed and examined by the user.

In addition, the cross-sectional width of the target section is automatically calculated by calculating the interval between the cross-sectional baselines. That is, according to the distance between the sectioned section and the section, the wall length in case of wall, beam length in case of beam, and column height information in case of column are automatically output.

The matching information generation module 53 models the form panel to the sectional shape information output from the sectional information output module 52 to generate the form matching information.

The matching information generation module 53 uses the sectional shape information output from the sectional information output module 52 to match the form panel to the outer surface of the member section.

For example, in the case of a wall, the form panel is matched by the height and width information of the wall in the cross-sectional shape information.

As a result, the calculation for the form panel modeling becomes very simple, and the automatic design program processing speed becomes very fast.

The display module 54 outputs and displays the form matching information.

The display module 54 may output the form panel information for each cross section by the matching information generating module 53 in the form of a table according to the user. Wherein the output includes being displayed on the user terminal.

The form matching information output to the display module 54 may include quantity information of each form panel type.

Accordingly, the form panels can be grouped by type, and the required form quantities of each type can be calculated, thereby providing the related form panel production information.

5 is a diagram showing a member information management window among the 2D cross-sectional shape information output from the 3D shape information.

The sectional shape information output from the sectional information output module 52 can be changed by the user.

The member information management window of the 2D cross-sectional shape information output from the 3D shape information of each member of the structure is shown in Fig.

5, the information output from the 3D shape information is set to a default value, and each data value can be configured to be changed by the user.

That is, since the form panel modeling data is matched to the sectional shape information, the change can be easily reflected in the automatic design of the form panel by merely changing the information of the member information management window at the time of design change.

FIG. 6 is a view showing a 2D view for outputting the form matching information, FIG. 7 is a view showing a 3D view for outputting the form matching information, FIG. 8 is a diagram showing the form matching information output from the 2D view or the 3D view, FIG.

The die matching information is linked to the 3D shape information generated by the 3D modeling module 51, and the display module 54 outputs the die matching information in association with the 3D shape information and displays the same.

The form matching information may be linked to the 3D shape information generated by the 3D modeling module 51 so that the user can output and confirm it according to the use.

Accordingly, the user can select and output the desired member and part from the 3D shape information.

At this time, a 2D viewer as shown in FIG. 6 or a 3D viewer as shown in FIG. 7 selects a desired position in the 3D shape information and outputs the form matching information as shown in FIG.

Since the die matching information is linked to the 3D shape information as well as the sectional shape information, the die matching information can be output in a state in which the die matching information is arranged on the member surface.

9 is a flowchart showing a method of generating workpiece matching information through a matching DB.

The form matching information may be generated by automatically matching the form panel information corresponding to the type of the design target cross-section to the target cross-section from the matching DB 55 that matches the form panel information for each cross-sectional type in advance.

Here, the process of generating the form matching information will be described. In the matching DB 55 in which the form panel information that is matched for each cross-sectional type is stored in advance, the cross-sectional type to which the target cross-section belongs is searched. Then, the form panel matching information is automatically generated by matching the form panel information corresponding to the form panel information.

The matching DB 55 may be data included in a central server and commonly used for a plurality of projects.

If the cross-sectional type matching the target cross-section is not searched in the matching DB 55, the user manually matches the new form panel information to the target cross-section, and the newly matched cross-form panel information is stored in the matching DB 55 Can be stored.

As the number of executed projects increases, various cross-sectional type information is stored in the matching DB 55, thereby improving the automation design efficiency of the form panel.

In the matching DB 55, connection object installation information for connecting the formwork panels facing each other according to the section type is set in advance, so that the connection object can be matched automatically together with the form panel information matching the design object section.

The wall, column, and beam members are installed on both sides of the member so that the form panels face each other. At this time, the facing dice panels are connected to each other by a connection object such as a form tie.

The connection object installation information such as the installation location and the number of such connection objects is determined by the member cross-sectional shape. Therefore, it is possible to match and allocate the connection object installation information for each cross-sectional type to the matching DB in which the information for each cross-sectional type is stored.

Thus, connection object modeling can be performed automatically.

In addition, by modeling the connection object installation information directly to match the form panels on both sides of each member, the inconsistency of the connection object installation position does not occur.

At this time, the material specification of the connection object can be automatically determined according to the member width information included in the cross-sectional shape information of the design target cross-section.

The 2D sectional shape information output from the sectional information output module 52 already includes the thickness information of the member. Accordingly, the material specification such as the length, the type, and the notch position of the connection object can be automatically determined and stored in the die matching information in the matching information generation module 53 without any additional setting.

10 is a view showing an attachment information management window among the 2D sectional shape information output from the 3D shape information.

In the matching DB 55, attachment information for attachment to the form is preset in advance for each cross-sectional type, so that the attachment information can be automatically matched with the form panel information matched to the cross-section of the object to be designed.

FIG. 10 shows an attachment information management window of the 2D sectional shape information output from the 3D shape information.

The cross-sectional shape information grouped by type includes various information such as the position and size of the window, the size of the opening, the number of corners, and the like. In general, the attachment attached to the form panel is determined by the cross-sectional information as described above.

Therefore, attachment modeling can be automatically performed by preliminarily matching and matching the attachment installation information to the matching DB 55 for each cross-sectional type.

The data of the attachment information management window is set to a default value by calling preset data in the matching DB 55, but it is also possible for the user to manually change the installation position or the like.

Similarly, the connection object information described above can be manually changed by the user.

1: Formwork panel
2: Tag means
3: Recognition means
4: inventory information processing means
5: Molding modeling means
51: 3D modeling module
52: Section information output module
53: Matching information generation module
54: Display module
55: matching DB

Claims (5)

The present invention relates to an automatic design of a form panel for constructing a reinforced concrete structure,
A tag means (2) having an identification code attached to the form panel (1) being held;
Recognition means (3) for recognizing information of the tag means (2);
Inventory information processing means (4) for receiving the information recognized by the recognition means (3), sorting the form panels (1) held by the form, and storing the quantity information for each classification;
A form modeling means 5 for modeling and matching the form panel 1 to the member shape information; Respectively,
The form modeling means 5 reflects the stored form panel information of the stock information processing means 4 to perform the form-only designing primarily by matching the formative panels that can be held, and then, Wherein the automatic design of the formwork panel (1) is performed by performing the remaining design by performing a secondary design by matching the new formwork panels.
delete The method of claim 1,
Wherein the inventory information processing means (4) stores the form panel history information.
The method of claim 1,
Wherein the tag means (2) is a bar code or a QR code imprinted on the rear surface of the formwork panel (1).
The method of claim 1,
The form modeling means 5 includes a 3D modeling module 51 for generating 3D shape information of a structure; A sectional information output module 52 for outputting sectional shape information from the 3D shape information generated from the 3D modeling module 51; A matching information generating module 53 for modeling the form panel to the sectional shape information outputted from the sectional information output module 52 to generate the form matching information; A display module 54 for outputting and displaying the die matching information; Wherein the automatic modeling system comprises:

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