KR100745336B1 - Laser Induced Thermal Imaging Apparatus and Method using the same - Google Patents

Abstract

The present invention relates to a laser thermal transfer apparatus capable of improving the adhesion between the substrate and the transfer layer of the donor film, and a laser thermal transfer method using the apparatus.

The laser thermal imager of the present invention is a laser thermal imager which forms a transfer layer of a donor film as a light emitting layer of an organic electroluminescent element by using a laser oscillator, the substrate stage including an electromagnet in the laser thermal imager, A close contact frame including a magnetic material is spaced apart from the upper portion of the substrate stage by a predetermined distance.

Accordingly, the adhesion property between the substrate and the transfer layer of the donor film can be improved, and the life, yield and reliability of the organic device can be improved.

 Lamination, Donor Film, Magnetic Material, Contact Sheet, Electromagnet

Description

Laser thermal transfer device and laser thermal transfer method using the device {Laser Induced Thermal Imaging Apparatus and Method using the same}

1 is a cross-sectional view of a laser thermal transfer apparatus according to the prior art.

2 is a perspective view of a laser thermal transfer apparatus according to the present invention;

3A is a perspective view of a substrate stage in accordance with the present invention.

Figure 3a is an enlarged perspective view of the substrate stage according to the present invention.

FIG. 3B is a cross sectional view taken along the line II ′ of FIG. 3A;

5 is a block diagram showing a laser oscillator according to the present invention.

6A to 6F are step-by-step cross-sectional views of the laser thermal transfer method using the laser thermal transfer apparatus of the present invention.

7 is a block diagram showing a laser thermal transfer method.

♣ Explanation of symbols for the main parts of the drawing ♣

  210: process chamber 220: laser oscillator

  230: close contact frame tray 240: donor film tray

  250: substrate 260: substrate stage

The present invention relates to a laser thermal transfer apparatus and a laser thermal transfer method using the apparatus, and more particularly, to provide a substrate stage with an electromagnet and an adhesion frame including a magnetic material, thereby improving the adhesion between the substrate and the transfer layer. Laser thermal transfer apparatus and laser thermal transfer method using the apparatus.

In general, at least a laser beam, a substrate, and a donor film are required to perform laser induced thermal imaging (LITI). The donor film includes a base substrate, a light-to-heat conversion layer, and a transfer layer.

In the laser thermal transfer step, the donor film is laminated on the substrate with the transfer layer facing the substrate, and then the laser beam is irradiated onto the substrate. The laser beam irradiated onto the substrate is absorbed by the light-heat conversion layer and converted into thermal energy, and the transfer layer is transferred onto the substrate by the thermal energy.

Hereinafter, a laser thermal transfer method according to the related art will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of the laser thermal transfer apparatus according to the prior art.

Referring to FIG. 1, a stage 110 is provided below the chamber 100. The stage 110 forms a first alignment groove 170 and a second alignment groove 180 to align the substrate 140 and the donor film 160, respectively. The second alignment groove 180 is formed to form a step with the first alignment groove 170. The substrate 140 is positioned along the shape of the first alignment groove 170 formed on the stage 110, and the donor is formed along the shape of the second alignment groove 180 formed on the stage 110. The film 160 is located.

After the donor film 160 is laminated on the substrate 140, a laser is irradiated onto the donor film 160 using the laser oscillator 190 to transfer a laser beam (transfer layer) of the donor film 160. Not shown) is transferred onto the substrate 140.

However, a gap or foreign material 150 may be included between the transfer layer (not shown) of the donor film 160 and the substrate 140. Therefore, the hose should be connected to one section of the lower region of the first alignment groove 170 and the second alignment groove 180 to suck oxygen or foreign matter into the vacuum pump 130.

In addition, this conventional technique is performed in the air, unlike other processes for manufacturing the organic light emitting device is carried out in the vacuum chamber, causing degradation of the reliability, lifespan and device characteristics of the organic light emitting device by oxygen and moisture.

In order to solve these problems, the transfer process of the organic light emitting device is performed in a vacuum chamber.

However, when the transfer process of the organic light emitting device is performed in a vacuum chamber, the reliability, lifespan, and device characteristics of the organic light emitting display device may be improved, but minute pores (pores) or foreign matter are generated between the transfer layer and the substrate. Even if the vacuum pump or the lamination method using the vacuum cannot be performed, the adhesiveness between the transfer layer and the substrate is further deteriorated.

Accordingly, the present invention has been made to solve the above-mentioned problems. The present invention provides a close contact between the substrate and the transfer layer of the donor film by providing a close contact frame including a magnetic substrate and a substrate stage provided with an electromagnet in the vacuum chamber. It is an object of the present invention to provide a laser thermal transfer method and a laser thermal transfer method using a donor film capable of improving the temperature.

According to an aspect of the present invention, to achieve the above object, the laser thermal transfer apparatus of the present invention in the laser thermal transfer apparatus for forming a transfer layer of the donor film as a light emitting layer of the organic electroluminescent element using a laser oscillator The substrate stage includes an electromagnet in the laser thermal transfer apparatus, and an adhesion frame including a magnetic material spaced apart from the upper portion of the substrate stage by a predetermined distance.

Preferably, a magnetic force acts between the electromagnet and the magnetic body, and the electromagnet includes electric wiring for applying a voltage.

The magnetic body is formed on any one of the upper part of the contact frame, the lower part of the contact frame or the inside of the contact frame, or the contact frame itself is the magnetic material. The magnetic material is formed of at least one material of iron, nickel, chromium or an organic material having magnetic properties, an inorganic material having magnetic properties, and magnetic nanoparticles, and the adhesion frame has an opening having a pattern corresponding to a portion to be transferred of the donor film. do.

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

2 is a perspective view of a laser thermal transfer apparatus according to the present invention.

Referring to FIG. 2, the laser thermal imager 200 includes a substrate stage 260 equipped with an electromagnet using a laser oscillator 220, a donor film 241 positioned above the substrate stage 260, and the The adhesion frame 232 is positioned on the donor film 241.

A substrate stage 260 having at least one electromagnet 264 is formed under the process chamber 210 of the laser thermal transfer apparatus 200. The substrate stage 260 is a stage for sequentially placing the substrate 250 and the donor film 241 introduced into the process chamber 210, respectively, and is located on the bottom surface of the process chamber 210.

The electromagnet 264 is formed on the inner surface of the groove 263 formed in the substrate stage 260. A coil or a concentric electromagnet 264 in which a coil is wound is formed in a predetermined region of the inner surface of the groove 263, and the electromagnet 264 is formed with an electrical wiring (not shown) for applying electric power. At this time, the electromagnet 264 is formed in a plurality of horizontal and vertical rows in order to perform laminating more advantageously.

The substrate 250 is positioned on the substrate support 265. The substrate 250 is seated on the substrate support 265 which is raised upward through a predetermined number of first alignment grooves 261 formed in the substrate stage 260, and then the substrate 250 is The seated substrate support 265 is lowered downward to mount the substrate 250 on the substrate stage 260. The substrate support 265 may be moved upward or downward through the first alignment groove 261 formed in the substrate stage 260. In this case, the substrate 250 includes a predetermined number of thin film transistors (not shown) formed in subpixel units.

The donor film tray 240 having the donor film 241 is positioned on the substrate 250. The donor film tray 240 having the donor film 241 is formed on the donor film support 266 that is raised upward through a predetermined number of second alignment grooves 262 formed in the substrate stage 260. After being mounted on the donor film support 266, the donor film tray 240 having the donor film 241 is mounted on the substrate stage 260 by lowering the donor film support 266 downward. An opening is formed in the center of the donor film tray 240, and the donor film 241 is interposed in the opening. The donor film 241 may include at least a substrate substrate, a light-to-heat conversion layer, and a transfer layer, and an intermediate layer may be further provided between the light-to-heat conversion layer and the transfer layer. When the donor film 241 is positioned on the substrate 250, the transfer layer of the donor film is positioned to face the substrate 250.

The close contact frame 232 including the magnetic material 234 forms a magnetic force with the electromagnet 264 formed inside the substrate stage 260, and is located between the close contact frame 232 and the close contact frame 232. The substrate 250 and the donor film 241 are strongly laminated. The magnetic body 234 may be formed on the upper, lower, or inner portion of the contact frame 232 or the magnetic body 234 itself as the entire contact frame 232. In addition, the close contact frame 232 is provided with an opening groove 233 through which the laser can pass, so that the close contact frame 232 is irradiated with a laser to the donor film 241. The opening groove 233 has a groove size corresponding to a portion to be transferred of the donor film 241.

The close frame moving means 231 is a means for causing the close frame frame 230 with the close frame 232 to reciprocate in the direction of the substrate stage 260.

The laser oscillator 220 is located above the process chamber 210. The laser oscillator 220 may be installed outside or inside the process chamber 210, and the laser oscillator 220 may be installed so that the laser generated from the laser oscillator 220 may be transferred on the donor film 241. Do.

3A is an enlarged perspective view of a substrate stage according to the present invention, and FIG. 3B is a cross-sectional view taken along the cutting line II ′ of FIG. 3A.

3A and 3B, a groove 263 is formed in the substrate stage 260. A bar-shaped electromagnet 264 in which a coil is wound is formed in a predetermined region of the inner surface of the groove 263. When the electromagnets 264 are arranged in a plurality of rows, electric power is applied only to the electromagnets to which the laser is irradiated to generate a close frame and magnetic force provided with a magnetic layer, and local lamination is continuously performed on the portion to which the laser is irradiated. Make it happen. In addition, although not shown, each electromagnet 264 is formed with an electrical wiring for applying electric power.

In the above-described embodiment, the electromagnets are arranged in a plurality of rows, but may be arranged concentrically.

4 is a perspective view of a close contact frame according to the present invention.

Referring to FIG. 4, the close contact frame 232 includes the magnetic body 234 and at least one opening groove 233.

Here, the magnetic body 234 forms a magnetic force with the electromagnet 264 formed in the substrate stage 260 shown in FIG. The magnetic layer 234 is made of a general material attached to the magnet, for example, iron (Fe), nickel (Ni), chromium (Cr) and their alloys (Fe ₃ O ₄ , CoFeO ₄ , MnFeO ₄ ) or attached to the magnet It consists of at least one of all inorganic and organic materials.

5 is a configuration diagram showing a laser oscillator according to the present invention.

The laser oscillator 220 is positioned above the donor film 241. The laser oscillator 220 may be installed outside or inside the chamber, and the laser oscillator 220 may be installed so that the laser generated from the laser oscillator 220 may be projected on the donor film.

 In addition, according to FIG. 5, which is a schematic configuration diagram of the laser oscillator 220, the laser oscillator in the present embodiment uses a CW ND: YAG laser (1604 nm) and includes two galvanometer scanners 221 and 222. The scan lens 223 and the cylinder lens 224 are provided, but the present invention is not limited thereto. The laser beam generated by the laser oscillator 220 passes through the lenses and is irradiated on the donor film 241 laminated on the substrate 250.

6A to 6F are step sectional views of the laser thermal transfer method using the laser thermal transfer apparatus of the present invention, and FIG. 7 is a block diagram showing the laser thermal transfer method.

Referring to FIG. 6A, in order to explain the present laser thermal transfer method, first, the robot arm 420 and an end effector 410 are loaded into the transfer chamber 400. The transfer chamber 400 preferably maintains a vacuum atmosphere. The substrate 250 is seated on the end effector 410 loaded in the transfer chamber 400. (See S1)

Referring to FIG. 6B, in order to transfer the substrate 250 seated on the end effector 410 into the process chamber 210, the end effector 410 is transferred to the process chamber 210. Transfer into chamber 210. Thereafter, the substrate 250 seated on the end-effector 410 is lifted upward through a predetermined number of through holes formed in the substrate stage 260. It is seated on the phase. The substrate support 265 may move upward or downward through a through hole of the substrate stage 260. Thereafter, in order to seat the substrate 250 on the substrate stage 260, the substrate support 265 is lowered to seat the substrate 250 on the substrate stage 260. An electromagnet (not shown) is provided in the substrate stage 260. At this time, the electromagnet is formed in a plurality of rows of horizontal and vertical in order to perform laminating more advantageously. In addition, the process chamber 210 preferably maintains a vacuum atmosphere. (See S2)

Referring to FIG. 6C, after mounting the substrate 250 seated on the end effector 410 on the substrate support 265, the end effector 410 may be referred to as the end effector 410. Transfer into the transfer chamber 400. Thereafter, the donor film tray 240 having the donor film 241 interposed thereon is positioned on the end effector 410. The donor film 241 includes a base substrate, a light-to-heat conversion layer, an intermediate layer, and a transfer layer.

Referring to FIG. 6D, the donor film tray 240 including the donor film 241 seated on the end effector 410 is moved into the process chamber 210. The donor film tray 240 moved into the process chamber 210 is seated on the donor film support 266. In addition, the transfer layer of the donor film 241 is positioned to face the upper portion of the substrate 250. (See S3)

Referring to FIG. 6E, the donor film tray 240 is seated on the donor film support 266, and then the end effector 410 is transferred into the transfer chamber 400. Thereafter, in order to laminate the donor film 241 of the donor film tray 240 seated on the donor film support 266 on the substrate 250, the close frame transfer means 231 is directed downward. The donor film 241 is laminated on the substrate 250 by descending to. (See S4)

Referring to FIG. 6F, power is applied to an electromagnet formed in the substrate stage 260 to improve the adhesion of the transfer layer of the donor film 241 on the substrate 250. Accordingly, a magnetic force acts between the electromagnet formed in the process chamber 210 and the adhesion frame 232 provided with the magnetic material, thereby further improving the adhesion characteristics between the substrate 250 and the transfer layer of the donor film 241. do.

The gate valve 300 formed between the transfer chamber 400 and the process chamber 210 is closed to transfer the transfer layer of the donor film 241 onto the substrate 250. At this time, the laser oscillator 220 formed inside or outside the process chamber 210 is operated to irradiate a laser onto the donor film 241. The laser oscillator 220 may be transported for each line to which the transfer layer is transferred. Accordingly, the transfer layer is transferred onto the substrate 250 to form the emission layer of the organic EL device. (See S5)

As described above, according to the present invention, the laser thermal transfer apparatus can laminate the transfer layer of the substrate and the donor film using a magnetic force in a vacuum state, thereby maintaining the lifetime, yield and reliability of the organic light emitting device. In addition, the laser thermal transfer device may further improve the adhesion between the substrate and the transfer layer of the donor film by providing an adhesion frame including a substrate stage and a magnetic material provided with an electromagnet.

Claims (10)

In the laser thermal transfer apparatus for forming a transfer layer of the donor film as a light emitting layer of the organic EL device using a laser oscillator, And a substrate stage including an electromagnet in the laser thermal transfer apparatus, and a close contact frame including a magnetic material spaced a predetermined distance from an upper portion of the substrate stage. The laser induced thermal imaging apparatus according to claim 1, wherein a magnetic force acts between the electromagnet and the magnetic body. The laser induced thermal imaging apparatus according to claim 1, wherein the electromagnet includes an electric wiring for applying a voltage. The laser induced thermal imaging apparatus according to claim 1, wherein the magnetic body is formed of at least one of iron, nickel, chromium, or an organic material having magnetic properties, an inorganic material having magnetic properties, and magnetic nanoparticles. The laser induced thermal imaging apparatus according to claim 1, wherein the magnetic material is formed at any one of an upper portion of the contact frame, a lower part of the contact frame, or an inside of the contact frame. In the laser thermal transfer apparatus for forming a transfer layer of the donor film as a light emitting layer of the organic EL device using a laser oscillator, And a substrate stage including an electromagnet in the laser thermal transfer apparatus, and a close contact frame formed of a magnetic material at a predetermined interval from an upper portion of the substrate stage. The laser induced thermal imaging apparatus according to claim 1, wherein the close contact frame has an opening having a pattern corresponding to a portion to be transferred of the donor film. The laser induced thermal imaging apparatus according to claim 1, wherein the substrate stage further comprises a substrate support for moving the substrate mounted on the substrate stage upward or downward through a predetermined number of through holes. Positioning the substrate on a substrate stage equipped with an electromagnet in the chamber; Placing a donor film having at least a substrate substrate, a light-to-heat conversion layer, and a transfer layer on the substrate; Positioning a close contact frame provided with a magnetic material on the donor film; Laminating the donor film on the substrate; And irradiating a laser beam onto the donor film to transfer a portion of the transfer layer of the donor film onto the substrate. 10. The method of claim 9, wherein the chamber is a vacuum chamber.

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