KR20150011175A - Integrated parametric modeling system and method for non-pattern - Google Patents

Abstract

The present invention relates to a system and method for integrated parametric modeling of an irregular frame, which are capable of easily modeling a shape image of an irregular frame structure member using parameters that are numerical information for shape or the like without directly depicting the shape image. The system includes: a boundary sensing module configured to sense a touch on a boundary line of a figure image displayed by a design application, and to generate a touch value by processing data on the position of the touch; a parameter input module configured to output a parameter input blank for an irregular frame structure member when the touch value or a select menu signal is received, and to generate an input value for drawing an image of the irregular frame structure member by processing data on a parameter inputted to the input blank; and a parameter calculating module configured to generate an output value for the image of the irregular frame structure member by processing the parameter included in the input value when the input value is received.

Description

An integrated parametric modeling system and method for non-stationary frames,

The present invention relates to an integrated parametric modeling system and method of an unstructured frame which allows a shape image of an irregular frame structure member to be easily modeled by using parameters, which are numerical information about a shape and the like,

Non-standard frame structural members such as longitudinal girder and transverse floor, which are basic aggregates of ships, are manufactured in various shapes according to functions and types without having a certain shape.

In order to manufacture an atypical frame structure member, a design drawing must first be prepared. Conventionally, an operator directly manipulates a design exclusive application such as a CAD to individually display each part of the atypical frame structure member, Displayed.

In general, the segment of the atypical frame structural member constituting the aggregate of the ship is divided into borders by the bending point, and is classified according to the number of the arm. On the other hand, the atypical frame structural member refers to an arm located at an intermediate portion of both ends of the web, and classifies the type according to the shape of the web. Also, due to the diversity in which the end connection at both ends of the atypical frame structure member belongs to one of the cut part (Snip) and the weld part (Weld), the atypical frame structural member is divided into various functions. That is, the types and shapes of the irregular-shaped frame structural members are so various.

Therefore, in order to create a design drawing of a specific ship, the operator has to deal with various kinds of irregular frame structure members of various types and shapes, and it is troublesome and troublesome.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above problems, and it is an object of the present invention to provide an integrated parametric modeling system and method of an unstructured frame capable of accurately and easily modeling an irregular frame structure member having a determined dimension We will do it.

According to an aspect of the present invention,

A boundary line detection module for detecting a boundary line touch of a figure image shown by the design-only application and processing data on the touch position to generate a touch value;

A parameter for generating an input value for drawing the atypical frame structure member image is generated by processing the data of the parameter input to the input field, Input module; And

A parameter calculation module for receiving the input value and processing parameters included in the input value to generate an output value for the corresponding irregular frame structure member image;

And an integrated parametric modeling system.

In the present invention, when an operator needs to show an irregular frame structure member constituted on a ship, it is possible to input the parameters of the irregular frame structure member without having to directly show the irregular frame structure members, The structural member can be shown, and the illustrated irregular frame structural member has the effect of being accurately shown according to the specified dimensions.

1 is an image showing an irregular frame structure member shown by the modeling system according to the present invention,
2 is a block diagram illustrating an embodiment of a modeling system according to the present invention,
3 is a flow chart showing an embodiment of a modeling method according to the present invention,
FIG. 4 is a view showing an image of an irregular frame structure member shown through a modeling system according to the present invention,
5 is a diagram showing a first window image output by the modeling system according to the present invention for parameter input,
6 is a diagram showing a second window image in which a modeling system according to the present invention outputs a reference,
7 is a diagram illustrating a third window image output by the modeling system according to the present invention for receiving detailed information,
8 is a diagram illustrating an irregular frame structure member output in a 2D format by the modeling system according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, It will be possible. The present invention is capable of various modifications and various forms, and specific embodiments are illustrated in the drawings and described in detail in the text. It should be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an image showing an irregular frame structure member shown in the modeling system according to the present invention. Referring to FIG.

The modeling system according to the present invention is an apparatus that can easily be shown by inputting corresponding parameters, as shown in the drawings.

As shown in FIG. 1, the section of the atypical frame structural member widely used as a material for ship building is divided into a section defined by the bending point as an arm, Arm refers to the Web. Therefore, the types of the irregular frame structure members are classified according to the number of the arms and the shape of the web.

For example, a 2-arm is an unstructured frame structure member divided into two arms around one bending point, and is usually formed in an 'a' shape, and a 3-arm is composed of three arms , And the 4-arm is an amorphous frame structural member divided into four arms around three bending points, and has an "a" shape having a bent end portion , 5 Arm is an atypical frame structure member divided into five arms centering on four bending points, and has a bent end shape.

On the other hand, since there is no separate arm between the two ends of the two arms, there is no configuration referred to as the Web. However, since the Arm exists between the two ends, the 3 to 5 Arm includes a configuration referred to as the Web.

Subsequently, the 2 arm is an irregular frame structure member image shown in a 'A' shape by confirming the web radius (WebR) of the bending portion. 3 Arm checks the length of the web curve parallel to the side shell and identifies the position of both ends of the web curve, Is an irregular frame structure member shown in a 'C' shape, and is composed of one Web. 4 Arm is an irregular frame structure member shown by 'A' in which the length of two web curves and the curvature radius of one bend therebetween are confirmed and the ends are bent. do. 5 Arm is an atypical frame structure member shown in a 'c' shape having end curved portions by confirming the length of three web curves connected in series and the curvature radius of two bend portions therebetween, Web.

As described above, conventionally, an operator directly manipulates a design-specific application to directly show an irregular frame structure member. However, the modeling system according to the present invention can be applied to a corresponding irregular frame structure member through the following selection and dimension input Can be easily shown.

FIG. 2 is a block diagram illustrating an exemplary embodiment of a modeling system according to the present invention. Referring to FIG.

The modeling system 20 according to the present invention can be realized in a 2D or 3D format by linking an irregular frame structure member image of 2D format schematically shown by an operator through a design exclusive application 11 in cooperation with a design- Convert to image.

The modeling system 20 for this purpose includes a parameter input module 21 and a boundary line detection module 22 for generating and processing data on parameters inputted through the input means 12 as input values and touch values respectively, A parameter calculation module 23 for calculating and checking the parameters, a reference storage module 24 for storing a reference relating to the irregular frame structure member image so that the operator can detail the irregular frame structure member, And an image output module (25) for receiving and processing the output value calculated by the image output module (23).

The parameter input module 21 outputs a window constituted by an input column so as to be able to input parameters for the irregular frame structure member, processes the data of the parameter inputted by the operator in the input field to generate an input value, To the parameter computation module (21). Here, since the input boxes presented by the parameter input module 21 according to the present invention are presented in the unit of the arm made up of the irregular frame structure members, the operator inputs each of the irregular frame structure member images to be displayed do. Finally, the parameters processed by the modeling system according to the present invention are in units of Arm.

In addition, the parameter inputted to the parameter input module 21 according to the present invention is not limited to the numerical information of the arm unit but may be the condition information. The description will be described in more detail below with reference to the drawings.

The boundary detection module 22 senses a touch on a boundary line in the graphic image of the irregular frame structure member shown by the design-only application 11, processes data on the touch position to generate a touch value, (21). To this end, the perimeter detection module 22 interlocks with the design-only application 11, and receives touch values of the perimeter and touch values for the touch position from the design-specific application 11.

For reference, the parameter input value inputted to the parameter input module 21 in the arm unit and the touch value of the boundary detection module 22 can be input through the conventional input means 12. [ Here, the input unit 12 may be a keyboard, a mouse, or the like, and may input a parameter input value through a keyboard and a touch value through a mouse. In addition, a touch screen or the like may be applied to the input means 12.

The parameter operation module 23 combines and computes the shape of the atypical frame structure member based on the parameter input value and the touch value input in the unit of arm, and transmits the output value to the image output module 25.

The parameter input value and the output value calculated based on the parameter input value will be described in detail while explaining the modeling method according to the present invention.

The reference storage module 24 stores corresponding image data in units of Arm so that input information that can not be transferred by the parameter input value can be transferred in the image format, and stores the image data in the parameter calculation module 23 together with the parameter input value. . For reference, a plurality of the image data are presented to the operator, and the operator selects one of them to allow the parameter calculation module 23 to display the detailed irregular frame structure member.

The image output module 25 receives the output value from the parameter operation module 23 and outputs the corresponding irregular frame structure member image based on the output value. Here, the image output module 25 may output the image of the irregular frame structure member itself through a separate output page, but may transmit the output value to the design-only application 11 so that the output page of the design- So that the irregular frame structure member image is output.

FIG. 3 is a flow chart showing an embodiment of a modeling method according to the present invention, FIG. 4 is a diagram showing an image of an irregular frame structure member shown through a modeling system according to the present invention, FIG. 6 is a diagram showing a second window image in which a modeling system according to the present invention outputs a reference, FIG. 7 is a diagram illustrating a modeling system according to the present invention, FIG. 8 is a diagram illustrating an irregular frame structure member output in 2D format by the modeling system according to the present invention, and will be described with reference to FIG. 8. FIG.

S10; Steps to run the modeling system

The modeling system 20 according to the present invention is interlocked with the design-only application 11 so as to sense the boundary of the graphic image shown in the drawing window 1 of the design- On the other hand, a menu window (not shown) of the design-only application 11 can be further reinforced with a selection menu (not shown) capable of executing the modeling system 20, The system 20 can be executed in conjunction with the design-only application 11.

In addition, the modeling system 20 can be executed independently of the design-only application 11 without having a separate selection menu in the design-only application 11. However, the modeling system 20 is structured so as to be able to receive the relevant data from the design-only application 11.

S20; Border Selection Step

The operator selects the boundary of the graphic image for the irregular frame structure member shown schematically in the design-only application 11. When the operator touches the boundary line according to the above rule, the design-only application 11 sets the corresponding touch value to the modeling system (for example, 20, and the borderline detection module 22 receives it. Here, the boundary line touch is performed in order of the arm boundary line formed by the arm.

In the embodiment of the present invention, as shown in FIG. 1, an operator sequentially touches the boundary line of the graphic image with respect to the irregular frame structure member in the counterclockwise direction, The boundary detection module 22 receives the touch value from the design-only application 11.

For reference, when the boundary detection module 22 is interlocked with the design-only application 11, the operator senses an action of touching the boundary line of the graphic image with respect to the irregular frame structure member, The touch value is generated and received.

S30; Parameter input step

The modeling system 20 according to the present invention outputs a first window W1 to which a parameter for indicating an irregular frame structure member image is input according to the selection menu operation signal reception or the touch value reception. In the first window W1, an input field for inputting various parameters is configured.

For reference, in the embodiment of the present invention, the first window W1 is classified into various sections so that the operator can selectively input different kinds of parameters. The first window W1 is divided into a first section 3, a second section 4 and a third section 5, and the first section 3 has a web curve related parameter And input fields for inputting the arm-related parameters constituting the atypical frame structure member are arranged in the second section 4 and the third section 5, respectively. In the embodiment according to the present invention, an arm constituting a two-arm shaped non-rigid frame structure member is disclosed. The corresponding arm is two arms formed at both ends according to the structural characteristics of the two-arm non-rigid frame structure member. Parameter or arm image.

The unstructured frame structural member used for ship construction has a curved section in which the cross-sectional shape gradually increases in consideration of the increasing bending moment at both ends. At this time, the combination of end references determined according to various reference and structure characteristics referenced at both ends is largely classified into Snip Connection and Weld Connecton, and each connection is defined in more detail according to detailed conditions.

The modeling system 20 according to the present invention may be applied to various types of combinations of the number of arms of the web and the type of the end connection at both ends in the middle part of the atypical frame structure member in order to image the atypical frame structure member having the above- Is parametrically defined as a standardized one integrated interface. For this purpose, the input box configured in the first window W1 is configured to receive parameters for modeling the irregular frame structure member image in units of Arm, and the operator inputs the parameters corresponding to the input boxes, The system 20 can easily and quickly process the modeling for the atypical frame structure member.

Hereinafter, the parameters received by the modeling system 20 according to the present invention will be described with reference to embodiments.

As shown in Fig. 5, the first window W1 in which the parameter input field is displayed is configured such that the parameters for the first section 3 in which the parameters for the web curve are input and the toe of the irregular frame structure member are input And the second and third sections (4, 5).

In the first section 3, a parameter input field for the shape of the web curve is arranged. The input field includes a field for inputting a length of a web curve parallel to a side shell as parameters, And a field for inputting the position of the both ends of the web curve as parameters. Meanwhile, the first section 3 may further include an input field for inputting a radius of curvature WebR of the bent portion formed in the atypical frame structural member as a parameter.

As described above (see FIG. 1), the web curve is composed of more than 3 Arms, and the radius of curvature WebR is composed of the irregular frame structure members excluding the 3 arms. On the other hand, if you enter parameters for web curve, 'Parallel' and 'Top Bot.' , And if you select 'Top Bot.', The operator enters the Top and Bottom positions of the atypical frame structure member.

For reference, when an irregular frame structure member having two or more web curves is illustrated, a section corresponding to the number of web curves is formed in the first section 3.

In the second and third intervals (4, 5), parameter input lines for the arm shapes at both ends of the 2-arm type irregular frame structure member image are arranged. The input fields include a 'Ref' button, an end reference image, A parameter input field for the length of the end portion and a hump position of the end portion, and a parameter input field for the entire length of the irregular frame structure member image.

Since the two arm type non-rigid frame structure members have two ends, the first window W1 constitutes the second section 4 and the third section 5 for parameter input at each end.

Next, when the 'Ref' button is clicked, the parameter input module 21 outputs the second window W2 for posting the end reference image 7 for referring to the shape of the end of the irregular frame structure member, The image data in the storage module 24 is retrieved and the corresponding end reference image 7 is posted to the second window W2 (see FIG. 6). The various end reference images 7 posted in the second window W2 are stored as image data in the reference storage module 24 as a reference to the end shape of the irregular frame structure member. On the other hand, when the operator selects one of the end reference images 7 of the worker second window W2, the parameter input module 21 displays the selected end reference image in the second and third sections 4 and 5 And outputs it to the corresponding section. For reference, when an operator clicks an end reference image outputted in the second and third sections (4, 5), the image is enlarged as shown (see the second section) so that the operator can easily So that they can understand it.

The reference to the selected end reference image is for selecting a basic outline. The specific size and the like of the atypical frame structure member include a parameter input field for the radius of curvature of the end portion, the length of the end portion and the position of the end portion, A parameter input field for the entire length of the member image, and the like. To this end, the parameter input module 21 outputs the corresponding parameter input field to the second and third sections 4 and 5, respectively, so that the operator can input the parameter in the corresponding input field.

Subsequently, the second and third sections 4 and 5 further include a selection switch 5a (Length of toe along edge) for inputting condition information. The selection switch 5a is set so that parameter input to the arm size is automatically performed without inputting specific numerical information one by one. More specifically, the length of the atypical frame structural member, which forms the internal structure of the ship, varies depending on the installation location according to the structural characteristics of the streamlined ship. Therefore, in order to illustrate an irregular frame structure member in the prior art, there has been a problem in that the corresponding arm size of the irregular frame structure member has to be input one by one for each Arm.

However, in the modeling system according to the present invention, the position of the configuration in which the corresponding arm of the irregular frame structure member abuts is limited to the condition information, and a numerical value about the position and size of the configuration is inserted into the parameter operation module 23, The calculation module 23 can automatically calculate and input the length of the corresponding arm according to the numerical value.

For example, if a plurality of atypical frame structural members arranged in parallel with each other are positioned on the same reference line at one end, while the other end is positioned at a finish line not parallel to the reference line, The length must be different. That is, in order to show the irregular frame structure members, the parameters for the length must be input. However, the numerical value of the position and the size of the reference line and the finish line is input to the parameter calculation module 23 in advance, the conditional information input environment is created by operating the selection switch 5a, The parameter calculation module 23 automatically calculates and extracts the length (parameter) between the reference line and the finish line of the atypical frame structure member from the numerical value, And generates an output value for showing the structural member image.

As a result, the modeling system according to the present invention can calculate the output value for image output by automatically checking the size of the arm according to input condition information without inputting individual parameters such as the arm size.

On the other hand, the operator can input additional information in addition to the above-mentioned parameters in order to detail the irregular frame structure member image. For this, the parameter input module 21 outputs a menu for 'Any another information' to the second window W2. When the operator clicks the menu, the parameter input module 21 displays a third window including the additional information input field W3.

The input field included in the third window W3 includes an input field for inputting the thickness Thick and the material of the irregular frame structure member. When the operator inputs a parameter in the input field, the parameter calculation module 23 computes an output value for an image of an unstructured frame structure member in 3D format, and the image output module 25 processes the 3D format image in accordance with the output value.

Therefore, the modeling system 20 according to the present invention processes the data of the parameters when the parameters corresponding to the input boxes output to the third window W3 are input, and outputs the images of the 3D format shown in Fig. 1, When the parameter input to the input box output to the third window W3 is excluded, the image of the 2D format shown in FIG. 8 is output.

On the other hand, when the parameter input module 21 outputs the first window W3 in response to the touch value received from the perimeter detection module 22, the irregular frame structure member, which is confirmed by the number of touches included in the touch value, The parameter input module 21 adjusts the number and configuration of the input boxes and the second and third sections 4 and 5 and the like posted in the first window W3.

S40; Image modeling steps

When all the information is inputted to the parameter, the operator clicks the input completion button to transmit the input completion signal to the parameter input module 21. When the parameter input module 21 receives the input completion signal, As an input value, and transmits it to the parameter calculation module 23.

The parameter computation module 23 computes a parameter according to the set program and outputs an output value which is final data of the irregular frame structure member corresponding to the input value.

For reference, the output value is general data for a typical output means 13 such as a monitor to receive and output it as a corresponding image.

S50; Irregular image output step

The image output module 25 receives the output value from the parameter operation module 23, and allows the output means 13 to output the irregular frame structure member through a normal process on the output value.

Meanwhile, the image output module 25 of the modeling system according to the present invention may pop up a separate output window 2 as shown in FIG. 1 to output the corresponding irregular frame structure member image itself, To the design-specific application 11 so that the image of the irregular frame structure member is output through the output page of the design-only application 11.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

11; Design-only application 12; Input means
13; Output means 20; Modeling system
21; Parameter input module 22; Border Detection Module
23; Parameter calculation module 24; Reference storage module

Claims (2)

A boundary line detection module for detecting a boundary line touch of a figure image shown by the design-only application and processing data on the touch position to generate a touch value;
And a controller for outputting a parameter input field for an arm of the atypical frame structure member having a shape formed by connecting a plurality of arms partitioned on the basis of a bending point when the touch value is received, A parameter input module for generating an input value for drawing the atypical frame structure member image, searching the reference storage module and processing the corresponding image data as a parameter input to the input field;
A parameter calculation module for receiving the input value and processing parameters included in the input value to generate an output value for the corresponding irregular frame structure member image; And
A reference storage module for storing a reference similar to the image of the irregular frame structure member as image data of Arm unit;
And a second parametric modeling unit for parametric modeling of the atypical frame. The method according to claim 1,
Wherein the parameter input module stores numerical values of a reference line and a finish line position at which both ends of the arm of the atypical frame structure member are in contact with each other, and when the condition information about the contact between the finish line and the arm is input to the input box, Computing a parameter of the Arm;
Wherein the at least one unstructured frame comprises at least one non-uniform frame.

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