KR20070037064A - A graphic designing method of drawing plural products in one sheet - Google Patents

Abstract

A multi-piece graphics design method suitable for avoiding unnecessary cost, time and effort was disclosed.

In this multi-dimensional graphics design method, a number of similar items are modeled and item group names are set based on geometry commands. The number of geometry instructions commonly used for modeling multiple similar articles is then retrieved, and a unique part number is assigned to each of the models for multiple similar articles depending on the number of retrieved geometry instructions. The models for a number of similar parts with unique part numbers are stored in one file with the item group name.

As a result, the modeling of the three-dimensional or two-dimensional model of a plurality of similar parts is performed efficiently, and the congruence between the real parts of the parts is increased. In addition, changes made common to many similar parts can be made quickly and accurately. As a result, the multi-purpose graphic design method according to the present invention can prevent the occurrence of errors and reduce unnecessary consumption of cost, time and effort.

 Geometry commands, similar items, three-dimensional, two-dimensional, family of parts, unique part number.

Description

A Graphic Designing Method of Drawing Plural Products in One Sheet

In order to better understand the drawings used in the detailed description of the invention, a brief description of each drawing is provided.

1 is a flowchart illustrating a step-by-step graphical design method of the multi-dimensional diagram according to an embodiment of the present invention.

FIG. 2 is a block diagram schematically illustrating a graphic system for performing the graphic design method illustrated in FIG. 1.

3A to 3C are diagrams illustrating three-dimensional models of similar parts to be exemplarily managed in the graphic design method of FIG. 1.

`` Explanation of symbols for main parts of drawings ''

10: program memory 20: data memory

30: input device 40: display device

50: graphics processor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a graphic design tool applied to a graphic system and used in the design of an article, and more particularly to a graphic design method for modeling a plurality of similar articles.

Conventional graphics systems allow users or designers of articles to easily construct or design models depicting existing or new articles. Such a graphic system is provided with a graphic design tool, that is, a graphic design method in the form of a program, which enables the drawing of a drawing or an article.

As a graphic design method provided in a graphic system, a two-dimensional graphic design method and a three-dimensional graphic design method are used. The two-dimensional graphic design method allows a planar model of an object or an article to be designed by a planar geographic command. In addition to the planar model, the drawings provided by this two-dimensional graphic design method describe the dimensions of the article, the processing method and the change history. Meanwhile, the 3D graphic design method allows a spatial model of an object or an article to be designed to be created or designed by a spatial geographic command. Drawings prepared by this three-dimensional graphic design method represent the actual shape of the part.

The two-dimensional drawing representing the planar model and the three-dimensional drawing representing the spatial model constitute one design drawing. Accordingly, a constant association is maintained between the two-dimensional drawing and the three-dimensional drawing. As a result, if there is a change in either the 2D or 3D drawing, the graphics system causes the other drawing to be modified based on the change. These two-dimensional and three-dimensional drawings are made to show only a model for one article. In other words, the current graphic design method has no choice but to model the article in the form of one article and one degree.

On the other hand, most articles, in particular parts, are designed with similar articles or parts that share a basic shape or characteristic and only a few have changed. In this case, the current graphic design method of the one article one degree method should model similar first articles and second articles in separate drawings, respectively. If there is a change in common to these similar first and second articles modeled, the article designer must make the same modifications to the drawings in which the first article is modeled and the drawings in which the second article is modeled. . In addition, an error may occur in the design drawing because a part of the correction work is not progressed or a dimension or the like is incorrectly written. Furthermore, the drawings for similar items should be classified and managed. For this reason, in the current graphic design method, not only waste of unnecessary costs but also unnecessary waste of time and effort are added to the user or component designer.

Accordingly, an object of the present invention is to provide a multi-layered graphic design method suitable for preventing unnecessary waste of time, time and effort.

According to an aspect of the present invention, there is provided a method of designing a multi-dimensional diagram according to an embodiment of the present invention, the method comprising: modeling a plurality of similar items based on a geometry command and setting an article group name; Retrieving a number of geometry instructions commonly used for modeling a plurality of similar articles; Assigning a unique part number to each of the models for a plurality of similar articles using the number of retrieved geometry instructions; And constructing models for a plurality of similar articles into one file having an article group name.

The step of assigning a unique part number includes: retrieving a model formed by the number of geometry commands while sequentially increasing the number of retrieved geometry commands, and assigning a unique item number sequentially increasing to the retrieved model. It is preferable to include.

The unique article number preferably includes a part number which sequentially increases from the article group name and the initial value.

According to the above configuration, in the multi-part graphic design method according to the present invention, a plurality of similar parts are modeled such that a three-dimensional or two-dimensional model is given with a unique part number and features of the shape of the part are given in one file (that is, , One drawing). As a result, the modeling of the three-dimensional or two-dimensional model of a plurality of similar parts is performed efficiently, and the congruence between the real parts of the parts is increased. In addition, changes made common to many similar parts can be made quickly and accurately. As a result, the multi-purpose graphic design method according to the present invention can prevent the occurrence of errors and reduce unnecessary consumption of cost, time and effort.

In addition to the objects of the present invention as described above, other objects, other advantages and other features of the present invention will become apparent from the detailed description of the preferred embodiment with reference to the accompanying drawings.

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

1 is a flowchart illustrating a step-by-step graphical design method of the multi-layer diagram according to a preferred embodiment of the present invention. The graphic design method shown in FIG. 1 is performed by a graphic processor 50 of the graphic system as shown in FIG. To this end, the graphical design method of FIG. 1 is stored in the program memory 10 shown in FIG. In this regard, the graphic system of FIG. 2 will be described in preference to the multi-layer graphic design method according to the embodiment of the present invention shown in FIG. 1.

Referring to FIG. 2, the graphics system includes a program memory 10, a data memory 20, an input device 30, and a display device 40 commonly connected to the graphics processor 50.

The program memory 10 stores various application programs related to functions performed or managed by the graphics system, including an operating program required for operating the graphics system. Of course, the program memory 10 also stores a multi-dimensional graphics design method as shown in FIG. The data memory 20 temporarily stores data processed or to be processed by the graphics processor 50. The input device 30 transmits a planar or spatial geographic command input by a user, for example, a component designer, and a command specifying a mode and a function to the graphic processor 50 in the form of data. The display unit 40 displays the information processed by the graphic processor 50 as well as the state of the graphic system. The graphics processor 50 not only operates the graphics system according to the operating program stored in the program memory 10 but also performs a function or operation designated by a user (or a developer in charge) according to the application program stored in the program memory 10. In addition to creating and managing drawings.

In conjunction with such a graphic system will be described a multi-dimensional graphics design method according to an embodiment of the present invention shown in FIG. For convenience of explanation, it is assumed that three similar parts are constructed or designed as a three-dimensional model, as shown in FIGS. 3A to 3C. The model shown in FIG. 3A is a basic part, the model shown in FIG. 3B is a first similar part in which a hole is added to the basic part, and the model shown in FIG. 3C is a second similar part in which a hole in the center portion is changed to a semicircular cross section. It is called. Although only three-dimensional models of similar parts are created or designed in the form of a single piece of art, it will be understood by those skilled in the art that two-dimensional models of the similar parts can be created or designed in a single piece of paper. You will know enough.

The graphics processor 50 of the graphics system illustrated in FIG. 2 first models each of the basic parts, the first and the second similar parts according to spatial geometry commands input by the user or the part designer, and thus, FIGS. 3A to 3C. Create or design the same three-dimensional models (step S100). Also, the graphics processor 50 retrieves the same number of geometric instructions commonly included in the models for the components thus created or designed (step S102). A number (for example, "0001") is assigned to a group of parts to be included in these similar parts (that is, base part, first and second similar parts) (step S104).

Subsequently, the graphics processor 50 searches whether the three-dimensional model of the component formed by the spatial geometry instructions equal to the number of retrieved geometry instructions is among the models shown in FIGS. 3A to 3C (step S106). If there is no model modeled with the spatial geometry commands equal to the number of retrieved geometry commands, the graphics processor 50 increases the number of retrieved geometry commands by "1" and then returns to step S106 (step S108). On the contrary, if there is a three-dimensional model modeled by the spatial geometry command equal to the number of retrieved geometry commands, it is checked whether at least one three-dimensional model has the same number of spatial geometry commands (step S110). If there is more than one three-dimensional model modeled by spatial geometry instructions that match the number of geometric instructions retrieved in step S110, the graphics processor 50 may determine the time modeled for the one or more retrieved three-dimensional models. In order, a part number having a form of "1" increasing to an initial number (for example, "A") is added to the part group number (that is, "0001"), and the unique part number (for example, " 0001A "). The graphic processor 50 assigns a unique part number generated to each of the one or more searched three-dimensional models, and adds the features of the part (step S112). If there is only one three-dimensional model modeled by spatial geometry instructions that match the number of geometric instructions retrieved in step S110, the graphics processor 50 may assign an initial number (eg, to the retrieved three-dimensional models). The part number of " A " is added to the above part group number (ie, " 0001 ") to generate a unique part number (for example, " 0001A "). In addition, the graphic processor 50 assigns the generated unique part number to the searched three-dimensional model and adds the features of the part (step S114). At this time, if a three-dimensional model of the basic part as shown in FIG. 3A is found, the unique part number of "0001A" and "Blend" of "Revolved" are added to this three-dimensional model. Further, the graphic processor 50 checks whether a three-dimensional model of a part not assigned a unique part number remains (step S116).

If there is a three-dimensional model of the part not assigned a unique part number in step S116, the graphics processor 50 increases the number of the retrieved geometry commands by "1" (step S118). The graphics processor 50 searches whether the three-dimensional model of the part formed by the spatial geometry instructions corresponding to the increased number of retrieved geometry instructions by one is among the models shown in FIGS. 3B and 3C (step S120). . If there is no model modeled with spatial geometry instructions equal to the number of geometry instructions retrieved, the graphics processor 50 returns to step S118. On the contrary, if there is a three-dimensional model modeled by the spatial geometry instruction equal to the number of geometric instructions retrieved in step S120, it is checked whether there is at least one three-dimensional model having the same number of spatial geometry instructions (step S122). ). If there is more than one three-dimensional model modeled by spatial geometry instructions that match the number of geometric instructions retrieved in step S122, the graphics processor 50 may determine the time modeled for the one or more retrieved three-dimensional models. The part number (eg, "B" and "C") in the form of "1" in increments of the previous number (eg, "A") in the sequence is assigned to the above part group number (ie, "0001"). ) And its unique part numbers (e.g., "0001B" and "0001C"). The graphic processor 50 assigns a unique part number generated to each of the one or more searched three-dimensional models, and adds the features of the part (step S126). If there is only one three-dimensional model modeled by spatial geometry instructions that match the number of geometric instructions retrieved in step S122, the graphics processor 50 may determine a previous part number (eg, For example, the part number (for example, "B") increased by "1" to "A" is added to the above part group number (ie, "0001"), and the unique part number (for example, "0001B"). ) The graphic processor 50 assigns the generated unique part number "0001B" to the searched three-dimensional model and adds the features of the part (step S114). At this time, if the 3D model of the first similar part as shown in FIG. 3B is found, the unique part number of "0001B" and the features of "Revolved", "Blend", and "Simple Hole" are added to the 3D model. Subsequently, the graphic processor 50 checks whether a three-dimensional model of a part not assigned a unique part number remains (step S128).

If there are no three-dimensional models of parts having no part numbers in steps S116 and S128, the graphic processor 50 configures the three-dimensional models to which the unique part numbers are assigned as one file and sets the file as the component group. A file name (ie, "0001.prt") with an extension (for example, ".prt") appended to the number (ie, "0001") indicating a three-dimensional drawing is stored in the data memory 20 (first Step S130). In this case, three similar parts are included in the file stored in the data memory 20 so that a three-dimensional model of three parts is represented in one drawing.

As such, in the graphical design method of FIG. 1, three similar parts are modeled to be given the geometrical features of the part together with a unique part number to constitute a file (ie, one drawing). As a result, the modeling of the three-dimensional model of the three similar parts is performed efficiently, and the congruence between the real parts of the parts is increased. In addition, changes made common to the three similar parts can be made quickly and accurately. As a result, the graphical design method of FIG. 1 can prevent the occurrence of errors and reduce unnecessary consumption of cost, time and effort.

Although the multi-dimensional graphic design method of FIG. 1 has been described as extreme for the modeling of a three-dimensional model, those skilled in the art will appreciate that the multi-dimensional graphic design method of FIG. It can be clearly seen that it can be modeled in one drawing.

As described above, in the multi-dimensional graphic design method according to the present invention, a plurality of similar parts are modeled so that a three-dimensional or two-dimensional model is given with a unique part number and features of the shape of the part are given in one file (i.e., One figure). As a result, the modeling of the three-dimensional or two-dimensional model of a plurality of similar parts is performed efficiently, and the congruence between the real parts of the parts is increased. In addition, changes made common to many similar parts can be made quickly and accurately. As a result, the multi-purpose graphic design method according to the present invention can prevent the occurrence of errors and reduce unnecessary consumption of cost, time and effort.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, and a person of ordinary skill in the art without departing from the spirit and scope of the present invention. It will be apparent that various modifications, changes, and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (3)

Modeling a plurality of similar items and setting an item group name based on the geometry command; Retrieving a number of geometry instructions commonly used for modeling the plurality of similar articles; Assigning a unique part number to each of the models for the plurality of similar articles using the number of retrieved geometry instructions; And And constructing models for the plurality of similar articles into a single file having the article group name. The method of claim 1, The unique part number assigning step may include: retrieving a model formed by the number of geometric instructions while sequentially increasing the number of the retrieved geometric instructions; And And assigning unique item numbers sequentially increasing to the retrieved models. The method according to any one of claims 1 and 2, The unique article number is a multi-piece graphic design method characterized in that it comprises a part number sequentially increasing from the article group name and the initial value.

Images