KR20030025044A - 3-Dimensional Figure Marking System and Method for the Same - Google Patents

Abstract

PURPOSE: A three-dimensional figure marking system which forms the three-dimensional figure by converting a three-dimensional figure into data combination of a two-dimensional figure to mark the two-dimensional figure on a transparent object in certain sequence and distance, and a method for marking the three-dimensional figure are provided. CONSTITUTION: The three-dimensional figure marking system comprises a laser irradiation part(20) for irradiating laser into a transparent object(10) for marking a three-dimensional figure to form a two-dimensional figure; a driving part(15) for moving the transparent object by continuously forming the two-dimensional figure formed on the transparent object along a direction perpendicular to the two-dimensional figure so that the three-dimensional figure is formed; and a control part(30) for simultaneously converting the three-dimensional figure into data combination of the two-dimensional figure by slicing the three-dimensional figure to be formed on the transparent object, forming the two-dimensional figure on the transparent object by controlling the laser irradiation part according to the data, and forming the two-dimensional figure into the three-dimensional figure by controlling the driving part so that the driving part moves the transparent object in a direction perpendicular to the two-dimensional figure, wherein the laser irradiation part comprises a laser generation part(21) and a path regulation part(22).

Description

3-Dimensional Figure Marking System and Method for the Same}

The present invention relates to a three-dimensional shape marking system and a method thereof, and more particularly to a three-dimensional shape marking system and method capable of forming a high-fidelity three-dimensional shape inside a transparent object.

Recently, three-dimensional shapes are formed inside transparent glass or crystals, and as a souvenir, other gifts are increasing. In particular, since the three-dimensional shape can be formed inside the transparent object according to the taste or personality, its availability can be said to be higher.

Laser is mainly used to form a three-dimensional shape in the transparent object as described above, in the case of domestic patent application No. 1999-0041699 (method for internal processing of crystal and glass and crystal products by the method) has a certain shape By forming parts that look like tiny dots inside the crystal, these same parts are contiguous or connected so that the desired shape or shape is formed inside the crystal.

In the case of the prior art as described above, as shown in Figure 1, it consists of a support (2) that is movable in the vertical and horizontal directions, and the laser irradiation unit (3) for irradiating the laser to a fixed position. Therefore, when the three-dimensional shape is to be formed on the crystal 1 according to the related art, the crystal is moved up, down, left and right according to the data of X, Y and Z axes of the three-dimensional shape. By moving the position of (1) to the three-dimensional shape is formed in accordance with the laser irradiated from the laser irradiation section 3 inside the crystal (1).

However, in the case of forming a portion that looks like dots by directly moving the support as described above, there is a problem in that the portion that looks like the dots is difficult to be precisely formed according to the shaking generated when the support is driven and the crystal is driven. In addition, since the laser irradiated from the laser irradiation unit is irradiated only to a fixed position to move only the support to form a three-dimensional shape, if the volume or weight of the crystal or glass increases to form a precise three-dimensional shape There is a problem that it is difficult to move.

In addition, in the case of continuously forming a three-dimensional shape only by the dots as described above, the three-dimensional shape consisting of a circular surface as a whole, such as an apple is difficult to implement, even if the implementation of the three-dimensional shape of the clear, precise and high There is a problem that the implementation does not work.

The present invention has been made to solve the above problems of the prior art, the object is to convert the three-dimensional shape to a combination of data of the two-dimensional shape by marking the two-dimensional shape on a transparent object in a predetermined order and intervals A three-dimensional shape marking system for forming a shape and a method thereof are provided.

1 is a view showing the configuration of a conventional three-dimensional shape marking system,

2 is a view showing the configuration of a three-dimensional shape marking system according to the present invention,

3 is a diagram illustrating a first example of slicing a three-dimensional shape in the three-dimensional shape marking system according to the present invention;

4A and 4B are diagrams illustrating a second example of slicing a three-dimensional shape in the three-dimensional shape marking system according to the present invention;

5 is a flow diagram illustrating a three-dimensional shape marking method according to the present invention.

<Explanation of symbols on main parts of the drawings>

10: transparent object 15: drive unit

20: laser irradiation unit 21: laser generation unit

22: path adjusting unit 23, 24: first and second galvano mirror

30: control unit

According to a feature of the three-dimensional shape marking system according to the present invention for solving the above problems, a laser irradiation unit for irradiating a laser to form a two-dimensional shape with a transparent object to mark the three-dimensional shape therein, and the transparent object The driving unit for moving the transparent object to form a three-dimensional shape is formed continuously in a direction perpendicular to the two-dimensional shape formed in the two-dimensional shape, and by slicing the three-dimensional shape to be formed on the transparent object 2 Convert the data into a combination of dimensional shapes and control the laser irradiation unit according to the data so that a two-dimensional shape is formed on the transparent object, and the driving unit controls the moving object in a direction perpendicular to the two-dimensional shape. And a control unit for forming the two-dimensional shape to form a three-dimensional shape.

Further, according to a feature of the three-dimensional shape marking method according to the present invention, the first step of forming a two-dimensional shape with a transparent object to form a three-dimensional shape therein, and the transparent object in the vertical direction of the two-dimensional shape And a second step of moving to the transparent object, and repeating the first and second steps until the three-dimensional shape is formed as the two-dimensional shape is continuously formed along the vertical direction on the transparent object.

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

As shown in FIG. 2, the three-dimensional shape marking system according to the present invention includes a driving unit 15 on which a transparent object 10 such as crystal or glass is desired to form a three-dimensional shape therein, and the driving unit 15. The laser irradiation unit 20 for irradiating a laser to the transparent object 10 placed on the transparent object 10 to form a two-dimensional shape on the transparent object, and the three-dimensional shape to be formed on the transparent object 10 in a combination of two-dimensional data. And converting the laser irradiation part 20 so that the converted two-dimensional shape is marked on the transparent object 10 and simultaneously moving the driving part 15 in the vertical direction of the two-dimensional shape. It consists of a control unit 30 so that it can be formed continuously.

As illustrated in FIG. 3, the controller 30 slices the three-dimensional shape A into units of planes and converts the plurality of two-dimensional shape data combinations a1 to an. Therefore, under the control of the controller 30, the laser irradiation unit 20 marks the two-dimensional shapes a1 to an inside of the transparent object.

In addition, as shown in FIG. 2, the laser irradiator 20 generates and outputs a laser irradiated to the transparent object 15, and a laser generated from the laser generator 21. The path adjusting unit 22 is configured to adjust a path so that a two-dimensional shape is formed on the transparent object.

The laser generated by the laser generator 21 may be an Nd-YAG fundamental wave or an Nd-YLF elementary file, but it is a UV laser that can be easily absorbed and transmitted inside the glass. The laser in the UV wavelength band mentioned in -61832 can be said to be the most suitable laser, so it can generate the laser of the YVO4 335 nm wavelength.

In addition, the path adjuster 22 adjusts the angle of the mirror according to the X-axis data and the Y-axis data of the two-dimensional shape converted by the controller 30 so that the laser generated by the laser generator 21 is transparent. It is possible to configure the first and second galvano mirrors (23, 24) to be irradiated to the object (10).

In particular, in the exemplary embodiment of the present invention, the first and second galvano mirrors 23 and 24 may include a rotation axis of the first galvano mirror 23 and a rotation axis of the second galvano mirror 24. It is positioned so as to be orthogonal to each other on the horizontal plane and the two-dimensional shape formed in (10). Accordingly, the angle of the first galvano mirror 23 is adjusted according to the Y-axis data of the slicing two-dimensional shape, and the second galvano mirror 24 is according to the X-axis data of the slicing two-dimensional shape. The angle is adjusted.

In addition, the driving unit 15 supports the transparent object 10 and moves up and down on the Z axis. After the laser irradiation unit 20 forms the first two-dimensional shape a1, the controller 30 The laser irradiation unit 20 may form the second two-dimensional shape a2 by moving downward along the Z axis perpendicular to the two-dimensional shape by the control of.

As the plurality of two-dimensional shapes a1 to an are continuously formed along the vertical direction through the above method, the three-dimensional shape A is ultimately formed inside the transparent object 10.

On the other hand, in the three-dimensional shape marking system according to the present invention, as shown in Figure 4a, the three-dimensional shape (B) is more excellent in the expression effect when viewed in a direction perpendicular to the two-dimensional shape formed on the transparent object 10 If present, the three-dimensional shape B as shown in FIG. 4A by slicing and converting the three-dimensional shape B2 in which the three-dimensional shape B1 is axially rotated as shown in FIG. 4B into two-dimensional shape data combinations. It can also be marked clearly and precisely.

Looking at the operation of the present invention configured as described above are as follows.

First, in the first step, the control unit slices the three-dimensional shape to be formed inside the transparent object in units of planes and converts the data into a combination of two-dimensional data. (S1)

In a second step, the controller controls the laser irradiation unit so that a two-dimensional shape of the data combination is formed on the transparent object. (S2)

In a third step, the controller moves the driving unit in a direction perpendicular to the first two-dimensional shape. (S3)

In a fourth step, the controller checks whether all the two-dimensional shapes of the data combination are formed on the transparent object, that is, the three-dimensional shape is completed. (S4)

In the fourth step, if the three-dimensional shape is not completed and there is a next two-dimensional shape of the data combination to be formed on the transparent object, the three-dimensional shape marking method according to the present invention returns to the second step. Under the control of the controller, a next two-dimensional shape is formed in the transparent object.

On the other hand, when the three-dimensional shape is completed in the fourth step, the three-dimensional shape marking method according to the present invention is terminated.

Here, in some cases, the fourth step may take precedence over the third step. That is, if the three-dimensional shape is completed after the two-dimensional shape is formed, the three-dimensional shape marking method is terminated. If the three-dimensional shape is not completed, the transparent object may be moved up and down to form the next two-dimensional shape. .

According to the three-dimensional shape marking system and method of the present invention configured as described above, a three-dimensional shape to be formed inside a transparent transparent object is sliced by a unit of plane, and then converted into a data combination of two-dimensional shape, and then a galvano mirror is formed. Form the two-dimensional shape inside the transparent object, move the support for supporting the transparent object in a direction perpendicular to the two-dimensional shape, and then form another two-dimensional shape of the data combination on the transparent object. By repeating the process to form a three-dimensional shape by precise position control inside the transparent object has the effect of reducing the time required to form the three-dimensional shape and to implement a more sharp and precise three-dimensional shape.

Claims (6)

A laser irradiation part for irradiating a laser to form a two-dimensional shape with a transparent object to mark a three-dimensional shape therein; A driving unit for moving the transparent object such that a two-dimensional shape formed on the transparent object is continuously formed in a direction perpendicular to the two-dimensional shape to form a three-dimensional shape; Slicing a three-dimensional shape to be formed on the transparent object is converted into a combination of data of a two-dimensional shape, and the laser irradiation unit is controlled according to the data so that a two-dimensional shape is formed on the transparent object, and the driving unit is the transparent object. And a control unit configured to control to move in a direction perpendicular to the two-dimensional shape so that the two-dimensional shape forms a three-dimensional shape. The method of claim 1, The laser irradiator generates a laser and outputs the laser; And a path adjuster for adjusting a path of the laser output from the laser generator according to data of the controller to form a 2D image on the transparent object. The method of claim 1, The controller rotates by slicing the axial rotation of the three-dimensional shape to rotate the three-dimensional shape to be formed inside the transparent object when there is a three-dimensional shape suitable for viewing in a direction perpendicular to the two-dimensional shape formed on the transparent object A three-dimensional shape marking system specially configured to convert to a combination of two-dimensional shape data. A first step of forming a two-dimensional shape with a transparent object to form a three-dimensional shape therein; A second step of moving the transparent object in the vertical direction of the two-dimensional shape, The first and second steps are repeated until the three-dimensional shape is formed as the two-dimensional shape is continuously formed in the transparent object along the vertical direction. The method of claim 4, wherein The three-dimensional shape marking method further includes the step of slicing a three-dimensional shape to be formed on the transparent object in the vertical direction before the first step, and converting the three-dimensional shape into a combination of two-dimensional shapes. Shape marking method. The method of claim 5, And a two-dimensional shape formed on the transparent object in the first step is a two-dimensional shape converted from the three-dimensional shape according to the conversion process.