KR101726184B1 - Method And Apparatus For 3-Dimensional Showing Animation Of Packing Box - Google Patents
Method And Apparatus For 3-Dimensional Showing Animation Of Packing Box Download PDFInfo
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- KR101726184B1 KR101726184B1 KR1020150161639A KR20150161639A KR101726184B1 KR 101726184 B1 KR101726184 B1 KR 101726184B1 KR 1020150161639 A KR1020150161639 A KR 1020150161639A KR 20150161639 A KR20150161639 A KR 20150161639A KR 101726184 B1 KR101726184 B1 KR 101726184B1
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- G06—COMPUTING; CALCULATING OR COUNTING
- G06T—IMAGE DATA PROCESSING OR GENERATION, IN GENERAL
- G06T13/00—Animation
- G06T13/20—3D [Three Dimensional] animation
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Abstract
Description
The present invention relates to a three-dimensional animation presentation method and apparatus for a packaging box, and more particularly, to a three-dimensional animation presentation method and apparatus for a three-dimensional animation presentation of a packaging box, And more particularly, to a method and apparatus for three-dimensional animation of a packaging box that is simple and easy to use even for a user who does not have a professional design ability to produce the box.
In general, the design of the packaging box will vary depending on the size and shape of the contents to be packed in the box, and the design of the packaging box may be changed in consideration of the packaging material and the area printed on the box surface.
The design tendency of the packaging box is to form a viewing window for exposing the package inside the box or to form a vent hole for the packaging box, and to form a unique structure and shape for the promotion of the product, It also helps.
It has been limited to meet the new conditions required for the packaging box design as described above. Because packing box design uses skilled CAD design workforce and expensive CAD program and after making samples, it is necessary to go through the process of repeating new operation and revision when difference from actual specification occurs. We had to get a development map of the desired packaging box.
In order to solve the problems of the conventional art described above, a series of processes for displaying a three-dimensional graphic of a packaging box are automatically provided based on basic information of a simple two-dimensional box, There is a need for a new way to provide a three-dimensional design of the packaging box that is easy to use and easy to use.
It is an object of the present invention to provide a three-dimensional animation capable of vividly grasping the structure and form of a packaging box from a two-dimensional developed view of a packaging box, thereby making it possible for a user who is not skilled in designing a three- And to provide a method and apparatus for directing a three-dimensional animation of a packaging box.
The three-dimensional animation rendering method of a packaging box according to an embodiment of the present invention includes a first step of creating a two-dimensional developed view of a packaging box by defining a shape and a size of a box laid out using a plurality of line segments; An animation file including an insertion position of a virtual rotation axis, a folding direction, a folding angle, and a timing, which can be inserted between the selected basic surfaces, is analyzed by analyzing the two-dimensional developed view of the packaging box generated in the first step A second step of storing; And a third step of loading the animation file stored by the second step and sequentially folding the packaging box according to the folding order of the parts of the expanded three-dimensional box.
The second step may include a second step of providing a predetermined thickness to the selected basic surface to form a corrugated board or a board, And a second step of inserting a cylindrical object to eliminate the curved bone that is generated.
Also, in order to generate the two-dimensional developed view, it is possible to directly draw the lines and directly designate the shape and the shape of the desired packaging box using the provided icon icons, and the animation file is an svg file .
The types of line segments used in generating the two-dimensional developed view are classified into a reference line, a fold line, and a cut line, and the reference line, the fold line, and the cut line are defined according to a predetermined display format.
If there is a hole in the basic plane of the two-dimensional developed plane in the process of selecting the basic plane in the second step, the basic plane is divided to generate a new basic plane, and the hidden line segments used in the division process are And is not visible in the display.
The third step includes a third step of performing a texture for expressing various colors and textures on the surface of the three-dimensional box when the animation file is loaded in the third step. In the case of performing the texture, the svg file is rasterized jpg file is obtained, and the acquired jpg file image is cut and mapped to the surface of the three-dimensional box.
In the second step, a tree structure for hierarchically representing a plurality of basic planes is generated so that a two-dimensional developed view of the packaging box can be displayed in a three-dimensional graphic, And is influenced by the position and rotation information of the surface.
In addition, in the third step, in the process of folding the box using the three-dimensional graphic, the joint object can be mapped in the three-dimensional box, and the joint object can prevent the flow of the contents And a storage compartment.
And a third step of modifying and editing the generated segment information of the two-dimensional developed map after reading the animation file stored in the second step, The two-dimensional developed view is simultaneously displayed, and it is easily confirmed whether or not it is corrected.
According to an embodiment of the present invention, there is provided a three-dimensional animation rendering apparatus for a packaging box, comprising: an input module for inputting a command of a user; Dimensional distribution of the packaging box created by drawing the lines according to the user's command to define the shape and size of the expanded box, and then selecting the basic plane and inserting the virtual rotation axis that can be inserted between the selected basic planes A developed view conversion module for storing an animation file including a position, a folding direction, a folding angle and a timing; And an output module for displaying a process of folding the packaging box according to the folding order of the parts of the expanded three-dimensional box using the three-dimensional viewer program for loading the animation file stored in the developed-view conversion module .
The developed-view transformation module may include a developed-view generation unit that generates a two-dimensional developed view using a developed-view creation tool, and an insertion unit that selects a basic surface of the generated two- An animation information processing unit for specifying an insertion position of the basic plane and the rotation axis analyzed by the developed view analyzing unit and animation information about a folding direction and a folding angle and timing of the rotation axis, And an animation file storage unit for storing an animation file including a rotation axis insertion position, a folding direction, a folding angle, and a timing, wherein the animation information processing unit applies a predetermined thickness to a basic surface, In the solidification process, one of the basic surfaces and the other basic surface are in contact with each other And a cylindrical object is inserted to smoothing the curved bone generated in the region.
In addition, the developed-view transformation module may include a texture processing unit for reading an svg file of a packaging box stored in the animation file storage unit and performing a texture, and the texture processing unit may include a svg file of a two- Dimensional image obtained by cutting the image of the jpg file corresponding to each basic surface in an image of the acquired jpg file and then mapping the cut two-dimensional image onto the surface of the three-dimensional box.
In addition, the developed-view transformation module includes a developed-view editor that modifies segment information included in the animation file stored in the animation file storage unit.
According to the present invention, since a series of processes for displaying the three-dimensional animation of the packaging box can be automatically performed from the two-dimensional developed view, it is possible to minimize unnecessary user intervention, It is easy and easy to use.
In addition, according to the present invention, since the three-dimensional design of the packaging box can be easily designed by using the development drawing tool for generating the two-dimensional developed view of the packaging box, various design patterns can be tested in a short time during the development of the new packaging box design .
In addition, according to the present invention, a plurality of packing boxes suitable for various conditions such as the type and size of the contents to be packed and the product characteristics of the packaging are preliminarily manufactured, and external users are connected by a network in a web environment, Can be provided.
1 is a block diagram of a three-dimensional animation rendering apparatus for a packaging box according to an embodiment of the present invention.
FIG. 2A is a two-dimensional developed view of a packaging box according to an embodiment of the present invention. FIG.
FIG. 2B is an exemplary screen showing a selection window for designating the shape and shape of a packaging box using a tool icon according to an embodiment of the present invention.
FIG. 2C is an exemplary view showing a dimension input window for specifying the dimensions of the packaging box according to the embodiment of the present invention.
2D is an exemplary screen showing a blue fold line and a red cut line in the generated two-dimensional developed view according to an embodiment of the present invention.
3A is a view for explaining an insertion position of a virtual rotation axis in a two-dimensional developed view according to an embodiment of the present invention.
FIG. 3B is a view for explaining an operation of giving a predetermined thickness to a base surface according to an embodiment of the present invention to solidify the cardboard or board. FIG.
FIG. 3C is a view showing bent corrugations formed at a portion where a basic surface and a basic surface are in contact with each other according to an embodiment of the present invention.
FIG. 3D is a view for explaining an operation of inserting a cylindrical object for smoothing the rolled bone shown in FIG. 3C.
FIG. 4A is a diagram for explaining a method of specifying types of line segments and animation information applied to a two-dimensional developed view of a packaging box according to an embodiment of the present invention. FIG.
FIG. 4B is a diagram illustrating a two-dimensional developed view of a packaging box created using a developed view creation tool according to an embodiment of the present invention. FIG.
FIG. 4C is a view for explaining the operation of numbering the basic planes of the two-dimensional developed view of the packaging box of FIG. 4B. FIG.
FIG. 4D is a diagram for explaining a process of dividing a basic plane in a two-dimensional developed view of the packaging box of FIG. 4C to designate a new basic plane.
FIG. 5A is a diagram showing a hierarchical tree structure for a two-dimensional developed view of the packaging box of FIG. 4C. FIG.
FIG. 5B is an exemplary screen for designating a character and number combination ID for a two-dimensional developed view displayed on a screen of an output module according to an embodiment of the present invention and displaying a tree structure thereon.
6 is a view illustrating a process of texturing a surface of a three-dimensional box on a two-dimensional developed view of a packaging box according to an embodiment of the present invention.
7A and 7B are exemplary screens for explaining a process of modifying the segment information of the two-dimensional developed view by the developed view editing unit according to the embodiment of the present invention.
FIG. 8 is a flowchart illustrating a three-dimensional animation rendering method of a packaging box according to the present invention.
FIGS. 9A to 9P are images obtained by capturing respective screens when a packaging box is folded and contents are contained in a three-dimensional animation. FIG.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A method and apparatus for producing a three-dimensional animation of a packaging box according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.
It is to be noted that the same components of the drawings are denoted by the same reference numerals and symbols as possible even if they are shown in different drawings.
In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.
Also, when a part is referred to as "including " an element, it does not exclude other elements unless specifically stated otherwise.
1, a three-dimensional
The
The
The developed
The developed
The developed
The developed
2D, the two-dimensional developed view Px generated by the developed
The developed-
In addition, the developed
The animation
3B, the base surface M1 on which the solidification has been completed has a total thickness of 2d (see FIG. 3B). In this case, Corrugated board or board.
On the other hand, when two basic surfaces formed of corrugated cardboard or board meet by the three-dimensional process, as shown in FIG. 3C, Cn) may occur.
When a three-dimensional graphic depiction of folding a three-dimensional developed view is simulated, a portion where the curved bone Cn is located can be observed unnaturally. Therefore, the animation
The line segments defining the basic plane corresponding to the two-dimensional developed view generated by the developed
When the svg file of the two-dimensional developed view stored in the animation
The exploded
When the svg file stored in the animation
In the process of folding a three-dimensional box like this, a three-dimensional object (hereinafter referred to as a joint object) can be mapped into a three-dimensional box. Here, the joint object corresponds to a storage compartment for preventing the contents or the contents to be inserted into the packaging box from flowing. The process of folding a three-dimensional box with this joint object mapped can also be performed. For this purpose, the junction
Hereinafter, a method of specifying the types of line segments and animation information applied to the two-dimensional developed view of the packaging box generated by the developed-
As illustrated in FIG. 4A, the types of line segments used when designing the developed view Px1 of the two-dimensional box can be classified into <base line>, <fold line>, and <cut line>. The display format and line segment information for each line segment are as follows. Based on the segment information, animation information included in the svg file of the packaging box is generated.
<Baseline>
Among the basic aspects, it draws with inverted T line segment that correspond to X axis, Y axis, and Z axis on the base plane which is a standard for animation production. The line segment length of each axis is 1 mm. The X axis represents the left and right direction, the Y axis represents the front and back direction, and the Z axis represents the up and down direction.
The display method of the reference line for the X axis, Y axis, and Z axis is determined according to the following rules.
X: BASELINE number -X-A-B
Y: BASELINE number-Y-A-B
Z: BASELINE number-Z-A-B-M-H-R
(Example 1)
BASELINE2-X-5-90
Explanation: This means that the X-axis reference line in the second drawing moves 5 mm in the X-axis direction from the reference point in the first drawing and rotates 90 ° with respect to the X-axis.
For reference, in "BASELINE2-NX-5-90", NX indicates the - direction (reverse direction when X is positive).
(Example 2)
BASELINE2-Y-10-30
Explanation: This means that the Y-axis reference line in the second drawing moves 10 mm in the Y-axis direction from the reference point in the first drawing and rotates 30 ° with respect to the Y-axis.
For reference, in "BASELINE2-NY-10-30", NY represents the -direction (the opposite direction when Y is positive).
(Example 3)
BASELINE2-Z-5-0-U-120-290
Explanation: This means that the Z-axis is the Z-axis reference line in the drawing No. 2, which is shifted by 5 mm in the Z-axis direction from the reference point in the first drawing and rotated 0 ° about the Z-axis. U of M stands for up, which means the animation movement when moving up and down. The
For reference, VU is used instead of U for virtual surfaces where the contents of the package are located. Quot; BASELINE2-Z-5-0-VU-120-290 ".
<Cutting line>
This is a line segment drawn from the developed view of the packaging box, following the "CUT-BASELINE number" display format.
(Example 4)
CUT-BASELINE1
Explanation: It refers to cutting line in drawing No. 1.
<Folding line>
"CREASE-folding sequence - folding direction - folding angle - BASELINE number" is used to indicate the folding line in the developed view of the packing box.
(Example 5)
CREASE-101-OUT-90-BASELINE1
Explanation: This means that in the first drawing, the first group is folded 90 ° outward from the first group. Here, 101 means folding 01th in
As illustrated in Fig. 4B, a line segment indicated by red in the developed view Px2 of the two-dimensional box corresponds to a <cut line>, and a line segment indicated by blue corresponds to a <folding line>. As described above, the developed-
The packaging box used as a product and generally used is not a simple form as shown in FIG. 2A, but a form and a size of a basic surface are complicated like a packing box of FIG. 4B. Furthermore, since holes may be formed in the base plane, it is necessary to distinguish the base plane according to a clear classification standard.
FIG. 4C is a diagram showing the two-dimensional developed view of the packaging box illustrated in FIG. 4B, in which the respective basic surfaces are designated and the corresponding basic surfaces are numbered. In FIG. 4C, If there is a hole in the surface, it is understood that the basic surface is divided to define a new basic surface. For example, the left basic plane corresponding to the
Describe the rules applied when dividing the basic plane.
Referring to FIG. 4D, the line segments indicated by red in the left and right sides are divided in the horizontal direction to connect the line segments defining the square holes, and the line holes are formed between the square holes in the left square hole and the right square hole, It is possible to form the basic surfaces divided into two parts by dividing the surface into upper and lower parts. Since the newly created line segment is an unnecessary line segment which does not correspond to the <cut line> and the " fold line ", it corresponds to the hidden line segment Ls which becomes invisible when displayed as a three-dimensional stereoscopic graphic.
Also, a plurality of small line segments are continuously and successively designed with respect to a curved line of an arc or an edge corresponding to a portion marked with an arrow in FIG. 4D.
As a preparation process for animating the folding motion from the two-dimensional developed view of the packaging box as a three-dimensional graphic, a tree structure is created based on the mutual relation between the basic surface and the basic surface and the rotation axis information. It is necessary to indicate a dimensional packaging box. To this end, the animation
The tree structure of the two-dimensional box expansion diagram (Px2) illustrated in FIG. 4C can be represented by a hierarchical tree structure using the number of planes as illustrated in FIG. 5A. In the tree structure, all the basic surfaces are influenced by the position and rotation information of the upper basic surface, and ultimately the upper basic surface is influenced by the position and rotation information of the reference basic surface which is the center of the animation. In FIG. 5A, when the upper base faces corresponding to the face numbers '1', '3', '6', '9' and '17' are targeted, the base face having the face number '2' It becomes the upper base plane.
5B is a diagram showing a developed view Px3 of a two-dimensional box when a plurality of basic faces constituting a developed view Px3 of a two-dimensional box, which is exemplarily displayed in the
The texture process of the three-dimensional box will be described with reference to FIG.
The
The exploded
FIG. 8 is a flowchart illustrating a three-dimensional animation rendering method of a packaging box according to the present invention.
The developed
The developed-
The animation
The animation
In addition, the animation
The
When the svg file stored in the animation
In the case where an animation file is stored based on the two-dimensional developed view, the process of loading the stored animation file and rendering the folding process of the packaging box as a three-dimensional animation will be described.
9A shows an operation of selecting "Load OBJ file" in the pull-down menu to load the contents to be packed in the execution screen. FIG. 9B shows the read joint object in three dimensions, and the shape and shape of the joint object can be confirmed by enlarging, reducing, and rotating the joint object. FIG. 9C is an exemplary screen showing a developed view of the stored animation file (svg file) in a three-dimensional graphic. 9D shows a three-dimensional joint object appearing on the screen when an image of the joint object is clicked on the right screen.
If the play button () is clicked in FIG. 9E, the three-dimensional developed view of the packaging box starts to be folded in order as shown in FIGS. 9F to 9P. In particular, in FIG. 9L, the joint object is inserted into the packaging box, and the developed view of the packaging box is completely folded as shown in FIG. 9O, and finally the cover of the packaging box is placed.
While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken as limitations. 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.
100: Three-dimensional animation directing device of packing box
110: input module
120: Output module
130: Exploded view conversion module
140: joint object storage unit
Claims (13)
In order to show a series of processes in which the two-dimensional developed view of the packaging box generated in the first step is completed with a virtual three-dimensional packaging box, the animation information obtained by analyzing the two- Wherein the base plane includes a base plane, an insertion position of a virtual rotation axis that can be inserted between the base planes, a folding angle and a folding angle of the base plane with respect to the rotation axis, A second step of storing an animation file configured in a hierarchical tree structure form based on the mutual relationship between the rotation axis information and the rotation axis information; And
The animation file stored in the second step is loaded and a two-dimensional developed view of the expanded state is displayed on the animation file in a hierarchical structure based on the position and rotation information of the topmost basic surface, which is the reference basic surface of the tree structure, A third step of three-dimensionally folding based on the stored animation information; Dimensional animation of the packaging box.
The second step includes a second step (2-1) of providing a selected basic surface with a predetermined thickness and making it into a corrugated board or a board, and a step (2-1) And a second step (2-2) of inserting a cylindrical object to eliminate curved corrugations.
In order to generate the two-dimensional developed view, lines can be directly drawn or drawn, or tool icons can be used to conveniently specify the shape and shape of a desired packing box,
Wherein the animation file is an svg file.
The types of line segments used in generating the two-dimensional developed view are classified into a reference line, a fold line, and a cut line,
Wherein the reference line, the fold line, and the cut line are defined according to a predetermined display format.
If there is a hole in the basic plane of the two-dimensional developed plane in the step of selecting the basic plane in the second step, the basic plane is divided to generate a new basic plane, and the hidden line segments used in the division process are visible Wherein the packaging box is characterized by a three-dimensional animation rendering method.
And a third step of performing a texture for representing various colors and textures on the surface of the 3D box when loading the animation file in the third step,
Wherein when the texture is performed, the svg file is rasterized to obtain a jpg file, and the obtained jpg file image is cut and mapped to a surface of the three-dimensional box.
In the third step, in the process of folding the box with the three-dimensional graphic, the joint object can be mapped into the three-dimensional box,
Wherein the joint object includes a storage compartment for preventing the contents of the packaging object or the contents to be inserted into the packaging box from flowing.
And a second step of modifying and editing the generated segment information of the two-dimensional developed map after reading the animation file stored in the second step,
Dimensional display of the original and a two-dimensional developed view of the original are simultaneously displayed on the screen of the output module so as to easily confirm whether or not the original is modified.
In order to show a series of processes in which the two-dimensional developed view of the packaging box generated by drawing lines according to the user's command and defining the shape and size of the expanded box is completed with a virtual three-dimensional packaging box, The animation information obtained by the analysis includes a basic plane which is a closed area enclosed by lines constituting the developed view, an insertion position of a virtual rotation axis that can be inserted between the basic planes, a folding direction and a folding angle of the basic plane with respect to the rotation axis, A development view transformation module for storing an animation file including a timing in a folding order, the animation information having a hierarchical tree structure based on a correlation between the basic planes and the rotation axis information; And
A two-dimensional developed view of the expanded state is displayed on a display screen of a tree structure based on the position of the topmost basic surface, which is the reference basic surface of the tree structure, and the sub- And an output module for displaying a process of folding the surface in three dimensions based on the animation information stored in the animation file.
The developed-view transformation module includes a developed-view generation unit that generates a two-dimensional developed view using a developed-view creation tool, a selection unit that selects a basic plane of the generated two- An animation information processing unit for specifying an insertion position of a basic plane and a rotation axis analyzed by the developed view analyzing unit and animation information about a folding direction and a folding angle and timing of the rotation axis, And an animation file storage unit for storing an animation file including an insertion position, a folding direction, a folding angle, and a timing,
The animation information processing unit may be configured to impart a predetermined thickness to the base surface and to solidify the base surface in a corrugated cardboard or a board shape and to smooth the curved bone occurring at a portion where one base surface and another base surface contact with each other, And the object is inserted into the box.
Wherein the developed view conversion module includes a texture processor for reading an svg file of a packaging box stored in the animation file storage and performing a texture,
The texture processor rasterizes the svg file of the two-dimensional box developed view generated by the developed view creation tool to obtain a jpg file image, crops the image corresponding to each basic surface from the image of the acquired jpg file, Dimensional image of the packaging box is mapped on the surface of the packaging box.
Wherein the developed view conversion module includes an expanded view editor for modifying segment information included in the animation file stored in the animation file storage unit.
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CN117274511B (en) * | 2023-11-22 | 2024-03-12 | 大家智合(北京)网络科技股份有限公司 | Box-type 3D preview system and method in packaging field |
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