KR20100087974A - Marking apparatus having digital micromirror device - Google Patents

Abstract

PURPOSE: A marking device is provided to reduce time for marking by arranging a component which is large and heavy on a stage and moving a component which is small and light through a driving unit. CONSTITUTION: A stage offers a space in which a marked substrate is settled. A digital micro mirror device(300) converts light which is generated from a light source unit into a pattern image. A first optical lens unit(200) induces light which is irradiated from the light source unit to the digital micro mirror device. A pattern transmission unit(600) is made of an image transmission optical fiber for irradiating a pattern image which is emitted from the digital micro mirror device to the substrate. A drive unit comprises a first guide, a second guide, and a pattern transmission unit driving part.

Description

Marking apparatus having digital micromirror device

The present invention relates to a marking apparatus having a digital micromirror device, and more particularly, a digital micromirror implemented to be marked on a substrate by irradiating a pattern generated through the digital micromirror device through an image transmission optical fiber. A marking apparatus with a device.

Main exposure process for manufacturing PDPs, shadow masks, PCBs, color filters, LCDs, semiconductors, etc., followed by identifiers (manufacturers, orderers, sellers) to identify wafers in workpieces such as semiconductor wafers, glass, etc. , A unique number, etc.) is performed, i.e., a titler process.

According to the prior art, the photolithography process used in the main exposure process can also be applied to the marking process. The photolithography process is a series of processes for forming a pattern on a wafer by exposing a mask having a specific pattern laid out. The photolithography process is performed by coating a photoresist, exposing with a photo mask, and exposing the photoresist. It consists of processes, such as image development. Therefore, when the marking process is carried out through the photolithography process, the manufacturing process is cumbersome, and there is a problem such that productivity is low due to a long time.

In order to compensate for this, a laser marking process using a laser has appeared. Laser marking is a field of thermal material processing that converts energy of a laser beam into heat, and refers to recording symbols, characters, and shapes by marking or discoloring the surface of an object using a high energy density of a laser. Laser marking can be applied continuously for a long time because no ink is required, and it is an environmentally friendly method in that solvent is unnecessary. The laser marking apparatus and method are classified into a scanning type, a mask type, and a mixed type according to the purpose of use. Among them, the scanning type irradiates the workpiece with high density laser light, and turns the laser light to a scanning mirror. It is a technology that scans laser spot light on the surface of a workpiece and draws and marks a desired pattern such as a symbol, a character, or a figure while instantaneously modifying a minute portion of the workpiece surface on which the beam spot is split with laser energy. The mask type is a technique of placing a mask on a workpiece and then marking by irradiating laser light on the mask, and the mixed type is a method of using both a scanning mirror and a mask. However, such a laser marking method uses a laser spot light to mark a pattern on a surface of a desired workpiece, which causes a long marking time.

In order to improve the problem of the marking method using laser spot light, an apparatus for converting laser light into a desired pattern image using a digital micromirror device and then irradiating and marking on a substrate has been developed. However, such a marking apparatus has a problem that it is not suitable to perform marking on a moving substrate because the size of the DMD head composed of a laser light source, a digital micromirror device, an optical system, and the like is large and heavy.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-mentioned conventional problems, and an object of the present invention is to provide a marking apparatus having a digital micromirror device capable of efficiently performing marking on a moving substrate and shortening the marking time. It is to provide.

According to an exemplary embodiment of the present invention, there is provided an apparatus, comprising: a stage providing a space in which a substrate to be marked is mounted; A light source unit for generating light; A digital micromirror device for converting light generated by the light source unit into a pattern image; A first optical lens unit for guiding light emitted from the light source unit to the digital micromirror device; A pattern transmission unit made of an image transmission optical fiber for irradiating the pattern image emitted from the digital micromirror device on the substrate; A first guide disposed in an upper portion of the stage, extending in a first axial direction, extending in a second axial direction intersecting the first axial direction, and movable in the first axial direction; And a driving unit including a second guide coupled to a first guide, and a pattern transmission unit driving unit rotatably coupled to one side of the second guide in a range of a predetermined radius, and one end of the image transmission optical fiber. Is fastened to the pattern transmission unit driver, and is provided with a marking apparatus having a digital micromirror device, characterized in that it is integrally driven with the pattern transmission unit driver.

The marking device is disposed on the stage, the speed measuring unit for measuring the moving speed of the substrate to be marked; And a control unit configured to control the digital micromirror device driver according to a pattern input signal, and a second controller to control a rotation radius and a rotation speed of the pattern transmission unit driver according to an output of the speed measuring unit. It includes more.

The marking device is disposed between the digital micromirror device and the other end of the image transmission optical fiber, and adjusts the focus to input the pattern image output from the digital micromirror device to the other end of the image transmission optical fiber. It further comprises a lens unit.

The light source unit includes a laser light source for generating laser light in the wavelength range of 350 nm to 360 nm.

The light source unit includes a plurality of light emitting diodes having wavelengths different from each other within an ultraviolet wavelength range; And a reflecting mirror unit for reflecting a plurality of lights generated by the plurality of light emitting diodes and incident the light into the first optical lens unit.

The light splitter may further include a light splitter configured to divide the light generated by the light source unit into a plurality. The digital micromirror device, the first optical lens unit, the pattern transmission unit, and the pattern transmission unit driver may also be provided in plurality. The light source unit is disposed between the first optical lens unit.

The marking device may be disposed at an upper portion or a lower portion of the stage, and captures a pattern image irradiated onto a substrate through the image transmission optical fiber; And an alignment measuring unit including an alignment determination unit that determines whether the pattern image is aligned based on the data photographed by the camera unit.

According to the output signal of the alignment determination unit, the first control unit controls the driving of the digital micromirror device, or the second control unit controls the driving of the pattern transmission unit driving unit.

As in the present invention, bulky, heavy components such as light source units, optical lens units, digital micromirror devices, etc. are placed on the stage, and small, light components, such as image transmission optical fibers, are moved through the drive unit. In this way, the marking device can be simplified and the moving speed can be increased. As a result, the marking time can be shortened.

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

1 is a schematic configuration diagram of a marking apparatus having a digital micromirror device according to an embodiment of the present invention, and FIG. 2 is a functional block of a marking apparatus having a digital micromirror device according to an embodiment of the present invention. It is also.

1 and 2, a marking apparatus having a digital micromirror device according to an embodiment of the present invention may include a light source unit 100, a first optical lens unit 200, and a digital micromirror device (DMD). Micromirror Device) 300, the second optical lens unit 400, the control unit 500, the pattern transfer unit 600, the drive unit 700, the alignment measurement unit 800, the stage 900 and the speed measurement unit 950.

In the marking apparatus shown in FIG. 1, the laser light source unit 110 is used as the light source unit 100. The laser light source unit 110 generates and irradiates laser light in a wavelength range of 350 nm to 360 nm. The laser light irradiated from the laser light source unit 110 is incident on the first optical lens unit 200.

The first optical lens unit 200 includes a focusing lens 210 and a fly's eye lens 220, the focusing lens 210 focuses and emits the light irradiated from the laser light source unit 110, and the fly's eye lens ( 220 refracts the light passing through the focusing lens 210 more uniformly. The laser light passing through the first optical lens unit 200 is incident to the digital micromirror device 300.

In the digital micromirror device 300, a plurality of pixels are arranged in a matrix to convert the light passing through the first optical lens unit 200 into a desired pattern image and reflect the light. The digital micromirror device 300 may be configured to adjust a reflection angle for each pixel, and thus may be converted into a desired pattern image and reflected by adjusting a reflection angle of each pixel according to a pattern input signal. The overall configuration of the digital micromirror device 300 and the configuration of each pixel will be described in detail with reference to FIGS. 3 and 4 below. The pattern image reflected through the digital micromirror device 300 is incident on the second optical lens unit 400.

The second optical lens unit 400 is disposed between the digital micromirror device 300 and an end portion of the image transmission optical fiber used as the pattern transmission unit 600 so as to receive the pattern image reflected through the digital micromirror device 300. It performs the function of adjusting the focus to be input to the end of the image transmission optical fiber.

The pattern transmission unit 600 transmits the pattern image input through the second optical lens unit 400 and irradiates onto the substrate that is the marking target, thereby marking the pattern image on the substrate. As the pattern transmission unit 600, an image transmission optical fiber is used. One end of the image transmission optical fiber, that is, the portion to which the pattern image is irradiated, is rotatably driven by the pattern transmission unit driver 750 within a predetermined radius range. As a result, the pattern image irradiated through the pattern transfer unit 600 can be irradiated onto the substrate while moving along any axis (for example, the direction in which the second guide below extends) on the substrate.

In this embodiment, the image transmission optical fiber used as the pattern transmission unit 600 is divided into quartz, multi-component quartz, and plastic, depending on the material. The quartz-based image transmission optical fiber has high transparency and excellent heat resistance, but lacks flexibility. It is easy to break and has a complicated process. In contrast, plastic-based image transmission optical fiber is characterized by high flexibility, easy handling and easy processing. In the case of the present invention, since the pattern transmission unit 600 requires flexibility, it is preferable to use a plastic-based image transmission optical fiber.

The stage 900 provides a space in which the substrate to be marked is seated, and a driving unit 700 for driving the pattern transfer unit 600 in a desired direction is disposed above the stage 900. The driving unit 700 includes a first guide 710, a second guide 720, and a pattern transmission unit driver 750. A detailed structure of the driving unit 700 will be described with reference to FIG. 5 below. . One end of the image transmission optical fiber is fastened to the pattern transmission unit driver 750, and is integrally driven with the pattern transmission unit driver 750.

The control unit 500 includes a first control unit 510 and a second control unit 520, and the first control unit 510 receives light incident according to a pattern input signal input through an operation PC connected to a marking apparatus. It controls the driving of the digital micromirror device to convert the pattern image into a desired shape. The second control unit 520 controls the movement and the speed of the driving unit 700, and more specifically, the rotation radius and the rotational speed of the pattern transmission unit driving unit according to the output of the speed measuring unit 950, the substrate ( 10) and the movement speed of the pattern transmission unit 600 is synchronized.

The speed measuring unit 950 is disposed on the stage 900 to measure the moving speed of the substrate to be marked. The alignment measuring unit 800 includes a camera unit 810 and an alignment determination unit 850. The camera unit 810 is disposed above or below the stage 900, and photographs a pattern image transmitted through an image transmission optical fiber and formed on a substrate, and the alignment determination unit 850 is photographed by the camera unit 810. It is determined whether the pattern image is aligned based on the data, and the determination result is transmitted to the control unit 500. The control unit 500 controls the digital micromirror device 300 or the driving unit 700 through the first control unit 510 or the second control unit 520 according to the output signal of the alignment determination unit 850. Adjust the alignment of the image.

3 is a schematic configuration diagram of a digital micromirror device used in the present invention, and FIG. 4 is a diagram illustrating a configuration of unit pixels of the digital micromirror device illustrated in FIG. 3.

3 shows a digital micromirror device 300 composed of a plurality of pixels 310 arranged in a matrix. Each pixel 310 is uniformly arranged horizontally and vertically, each of which is independently controlled to be driven by a control unit. The pixel 310 rotates a predetermined angle about a rotation axis (not shown) to reflect the incident light to the marking object. The control unit 500 receives pattern information as an input signal from a pattern information source (for example, an operating PC), and transmits a pattern signal according to the received pattern information to each pixel 310 of the digital micromirror device 300. Thus, the plurality of pixels 310 are independently driven to convert light incident on the digital micromirror device 300 into pattern light of a desired pattern image.

Looking at the configuration of each pixel with reference to Figure 4, each unit pixel 310 is the main body 311, the support 312, the driving unit 313, the pillar 314, the reflector plate 315 and the rotation axis (not shown) It is composed.

The support part 312 is installed in the main body 311 so as to support the corners of each of the reflecting plates 315. The driving part 313 is rotatably coupled to the support part 312 and has a pillar 314 on which a reflecting plate 315 is fixed. The rotating shaft is hingedly connected to each support 312 formed at four corners in a cross shape on the lower surface of the driving unit 313 so that the driving unit 313 is movably supported by the support unit 312. The control unit 500 drives the motor by the signal input by the user so that individual reflection is made in each pixel 310, thereby generating a pattern image.

5 is a schematic perspective view of a marking apparatus having a digital micromirror device according to an embodiment of the present invention, and FIGS. 6A and 6B are diagrams for describing a driving method of a pattern transfer unit according to a transfer of a substrate to be marked. to be.

5 to 6B, the marking apparatus having the digital micromirror device includes a pattern generating head 1000, a pattern transmitting unit 600, a driving unit 700, a stage 900, and a control unit (not shown). And an alignment measuring unit (not shown). In the present exemplary embodiment, the pattern generating head 1000 is connected to the light source unit 100, the first optical lens unit 200, and the digital micromirror device (DMD) 300 and the second optical lens unit 400. The pattern generation head 1000 is separated from the driving unit 700 and disposed above the stage 900.

The stage 900 provides a space in which the substrate to be marked is seated, and a driving unit 700 for driving the pattern transfer unit 600 in a desired direction is disposed above the stage 900. The driving unit 700 includes a first guide 710, a second guide 720, and a pattern transmission unit driver 750. The first guide 710 is disposed above the stage 900, extends in the first axial direction, and the second guide 720 extends in the second axial direction crossing the first axial direction. It is coupled to the first guide 710 to be movable in the first axis direction. The pattern transmission unit driver 750 is rotatably disposed on one side of the second guide 720 in a range of a predetermined radius.

One end of the pattern transmission unit 600 is connected to the pattern generation head 1000, the body portion of the pattern transmission unit 600 is disposed along the second guide 720, and the other end of the pattern transmission unit 600. Is fastened to the pattern transmission unit driver 750, and is integrally driven with the pattern transmission unit driver 750.

The pattern transmission unit driver 750 is rotatably fastened to one side of the second guide 720 within a predetermined radius range. When the substrate 10 to be marked is conveyed in any axial direction, for example, in the direction in which the second guide 720 extends, the pattern transfer unit driver 750 is driven to rotate in a clockwise or vice versa direction. The end of the resulting pattern transfer unit 600 is reciprocated along any axial direction. By measuring the moving speed of the substrate through the speed measuring unit and controlling the rotation speed and the turning radius of the pattern transfer unit driver 750 according to the moving speed of the substrate, marking by irradiating the pattern image on the substrate to be transported for a predetermined time This can be done.

7 is a schematic structural diagram of a marking apparatus having a digital micromirror device according to another embodiment of the present invention.

Referring to FIG. 7, a marking apparatus having a digital micromirror device according to another embodiment of the present invention may include an optical unit 100 including a plurality of light emitting diodes 120, 130, and 140 and a reflective mirror unit 150. First optical lens unit 200, Digital Micromirror Device (DMD) 300, second optical lens unit 400, control unit 500, pattern transfer unit 600, drive unit 700 ), Alignment measuring unit 800, stage 900 and speed measuring unit 950. The marking apparatus according to the present embodiment has a different configuration of the light source unit as compared with the previous embodiment, and the rest of the configuration is similar, and will be described below based on different configurations.

The light source unit 100 includes a first light emitting diode 120 having a first wavelength λ ₁ , a second light emitting diode 130 having a second wavelength λ ₂ , and a third light having a third wavelength λ ₃ . Three light emitting diodes 140 are included, and the first to third light emitting diodes 120, 130, and 140 are configured to have different wavelengths within the ultraviolet wavelength range. The reflective mirror 150 reflects the light emitted from the first to third light emitting diodes 120 to the first optical lens unit 200.

8 is a schematic structural diagram of a marking apparatus having a digital micromirror device according to another embodiment of the present invention.

Referring to FIG. 8, in the marking apparatus including the digital micromirror device according to another embodiment of the present invention, the laser light source unit 110 and the light splitter 230 for dividing the light generated from the laser light source unit 110 into a plurality of parts. And a plurality of first optical lens units 241, 242, and 243 for guiding the light split through the light splitter 230 to the plurality of digital micromirror devices 330, 360, and 390, respectively. A plurality of patterns for inputting the pattern image generated by the first control unit 511, 512, 513 and the plurality of digital micromirror devices 330, 360, and 390 to the plurality of pattern transmission units 610, 620, and 630. Second optical lens units 411, 412, 413, a plurality of pattern transfer units 610, 620, 630 and a plurality of pattern transfer units for transmitting a pattern image generated through the plurality of digital micromirror devices 330, 360, 390 Pattern transmission metaphor It consists of a drive unit (751, 752, 753).

According to the above configuration, it is possible to mark a plurality of pattern images on the substrate at the same time, thereby significantly increasing the marking speed.

What has been described above is merely an exemplary embodiment of a marking apparatus with a digital micromirror device according to the present invention, and the present invention is not limited to the above-described embodiment, as claimed in the following claims, Without departing from the gist of the invention, anyone of ordinary skill in the art to which the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

1 is a schematic configuration diagram of a marking apparatus having a digital micromirror device according to an embodiment of the present invention.

2 is a functional block diagram of a marking apparatus with a digital micromirror device according to an embodiment of the present invention.

3 is a schematic structural diagram of a digital micromirror device used in the present invention.

4 is a diagram illustrating a configuration of unit pixels of the digital micromirror device illustrated in FIG. 3.

5 is a schematic perspective view of a marking apparatus with a digital micromirror device according to an embodiment of the present invention.

6A and 6B are diagrams for describing a driving method of a pattern transfer unit according to a transfer of a substrate to be marked.

7 is a schematic structural diagram of a marking apparatus having a digital micromirror device according to another embodiment of the present invention.

8 is a schematic structural diagram of a marking apparatus having a digital micromirror device according to another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

100: light source unit 200: first optical lens unit

300: digital micromirror device 400: second optical lens unit

500: control unit 600: pattern transfer unit

700: drive unit 800: alignment measurement unit

900 stage 950 speed measurement unit

Claims (8)

A stage providing a space in which the substrate to be marked is seated; A light source unit for generating light; A digital micromirror device for converting light generated by the light source unit into a pattern image; A first optical lens unit for guiding light emitted from the light source unit to the digital micromirror device; A pattern transmission unit made of an image transmission optical fiber for irradiating the pattern image emitted from the digital micromirror device on the substrate; A first guide disposed in an upper portion of the stage, extending in a first axial direction, extending in a second axial direction intersecting the first axial direction, and movable in the first axial direction; A driving unit including a second guide coupled to a first guide, and a pattern transmission unit driving unit rotatably coupled to one side of the second guide in a range of a predetermined radius, One end of the image transmission optical fiber is fastened to the pattern transmission unit driving unit, the marking apparatus having a digital micromirror device, characterized in that driven integrally with the pattern transmission unit driving unit. The method of claim 1, A speed measuring unit disposed on the stage, the speed measuring unit measuring a moving speed of the substrate to be marked; And A control unit including a first control unit for controlling the driving of the digital micromirror device in accordance with a pattern input signal, and a second control unit for controlling the rotation radius and the rotational speed of the pattern transmission unit driver in accordance with an output of the speed measuring unit. Marking apparatus having a digital micromirror device further comprising. The method of claim 1, A second optical lens unit disposed between the digital micromirror device and the other end of the image transmission optical fiber, for adjusting a focus of the pattern image output from the digital micromirror device to be input to the other end of the image transmission optical fiber Marking apparatus having a digital micromirror device, characterized in that it comprises. The method of claim 1, And the light source unit comprises a laser light source for generating laser light in the wavelength range of 350 nm to 360 nm. The method of claim 1, wherein the light source unit, A plurality of light emitting diodes having wavelengths different from each other within an ultraviolet wavelength range; And And a reflecting mirror unit for reflecting a plurality of light generated from the plurality of light emitting diodes to be incident on the first optical lens unit. The method of claim 1, Further comprising a light splitter for dividing the light generated by the light source unit into a plurality, The digital micromirror device, the first optical lens unit, the pattern transmission unit and the pattern transmission unit driver are also configured in plural, and the light splitter is disposed between the light source unit and the first optical lens unit. Marking apparatus provided with a digital micromirror device. The method of claim 2, A camera unit disposed above or below the stage and configured to photograph a pattern image irradiated onto a substrate through the image transmission optical fiber; And And an alignment measuring unit comprising an alignment determination unit that determines whether the pattern image is aligned based on the data photographed by the camera unit. The method of claim 7, wherein The first control unit controls the driving of the digital micromirror device, or the second control unit controls the driving of the pattern transfer unit driving unit according to the output signal of the alignment determination unit. One marking device.

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