KR100272599B1 - Printing squeeze using supersonic wave - Google Patents

Abstract

The present invention relates to a printing squeeze, the liquid is filled with a liquid material and the liquid ejecting part is ejected, the ejection control unit for controlling the amount of the liquid material ejected from the liquid ejecting part, and the liquid material ejected from the liquid ejecting part Ultrasonic vibrator for vibrating the ultrasonic wave cycle and a roller portion for rolling the liquid material ejected by the liquid ejecting portion coated on the substrate while uniformly applying the liquid material ejected by the liquid ejecting portion to a predetermined substrate Almost no liquid material can be easily applied to the entire surface of the substrate, there is an effect that can uniformly apply the liquid material to the large area panel.

Description

Ultrasonic Printing Squeeze

The present invention relates to a squeeze for printing, and to a squeeze that can evenly apply a liquid substance to the entire surface of the substrate.

Flat panel display devices such as a plasma display panel (LCD) or a liquid crystal display (LCD) include an electrode and a dielectric layer. There are various methods for manufacturing such electrodes and dielectric layers, but among them, screen printing is the most widely used method because the manufacturing cost is low and the process is simple. The key process equipment of this screen printing method is a squeeze.

1 illustrates a screen printing method in which a printing paste is applied to a part of a substrate by using a general squeeze.

In the screen printing method, a predetermined mask 20 is first placed on a substrate 10, and then a substance 40 to be applied on the substrate 10 is placed on the mask in a later step. Then, the paste is pushed into the squeeze 30 so that the material 40 is printed onto the substrate 10 through the mask 20. At this time, by using a mask of various shapes, it is possible to apply the paste material in various shapes on the substrate. In addition, in order to apply the material by the conventional squeeze used in such a general screen printing method, the material must be made in the form of a paste having a viscosity of a certain level or more.

At this time, the conventional squeeze shown in Figure 1 must push the printing paste having a viscosity of a predetermined level or more. This is because, if the material to be printed on the substrate is a liquid having almost no viscosity, pushing the liquid material with a conventional squeeze may cause the material to flow down without being applied onto the substrate. Due to this condensation, the conventional squeeze must always push a paste having a certain level of viscosity.

By the way, in general, such a viscous paste is produced by adding an organic solvent or the like to a predetermined coating agent. At this time, the coating agent to which the organic solvent is added increases in viscosity, but results in high quality of impurity concentration. For example, the MgO protective thin film forming a part of the plasma display panel, when mixed with the organic solvent, is inferior in transparency, resulting in lowering the light transmittance of the plasma display panel.

However, if a liquid substance without adding an organic solvent or the like to the coating agent is placed on the substrate in order to reduce the impurity concentration, as described above, the conventional squeeze has a problem that the liquid substance cannot be applied to the substrate. Therefore, the conventional squeeze has a disadvantage that the liquid material having a low viscosity cannot be applied to the substrate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a squeeze that can uniformly apply a liquid substance having almost no viscosity to the entire surface of a large area substrate.

1 is a view showing a screen printing method for applying a liquid material to a portion of a substrate using a common squeeze.

Figure 2 is a perspective view showing the structure of the printing squeeze according to the present invention.

Figure 3 is a cross-sectional view showing the detailed structure of the liquid ejecting portion and the ejection control portion of the squeeze shown in FIG.

Figure 4 is a view showing that the roller is installed in the roller portion of the squeeze shown in Figure 2 the alignment state is deformed by the irregularities of the substrate.

Explanation of symbols for main parts of the drawings

100: liquid jet part 200: jet control part

210: pressure unit 220: pressure control unit

300: ultrasonic wave oscillator 400: roller portion

410, 420, 430: Roller 500: squeeze body

600: liquid material 700: substrate

710: protrusion of the substrate 720: depression of the substrate

The present invention is characterized in that the liquid material can be evenly dispersed by attaching a hole and an ultrasonic vibrator using a capillary phenomenon.

Printing squeeze 500 of the present invention by the liquid ejecting part 100, the ejection control unit 200 for adjusting the ejection amount of the liquid material as shown in Figure 2, the liquid ejection part It comprises an ultrasonic vibrator 300 for vibrating the liquid material to be ejected, and a roller unit 400 for evenly applying the liquid material on the substrate. In addition, the interior of the squeeze 500 of the present invention serves as a kind of liquid container in which the liquid material is stored.

The liquid ejection part 100 is a kind of capillary tube, and ejects the liquid material at a constant ejection speed. The liquid ejection part 100 is a kind of narrow elongation at the bottom of the squeeze 500, and the width of the gap is controlled by the ejection control part to control the ejection speed of the liquid material.

Then, the ejection control unit 200 adjusts the ejection amount of the liquid material is constantly ejected by the liquid ejection unit 100. The spray control unit 200 is composed of a pressing unit 210 for applying pressure to a part of the liquid ejecting unit 100, and a pressure adjusting unit 220 for adjusting the pressure of the pressing unit as shown in the cross-sectional view shown in FIG. It is.

The pressurizing portion 210 of the ejection control part is composed of a kind of screw, and by applying pressure to a part of the liquid ejection part 100 according to the control made in the pressure adjusting part 220, the ejection amount and the ejection speed of the liquid substance 600. Adjust The pressure adjusting unit 210 is composed of a control screw or a switch to adjust the pressure applied to the liquid ejecting unit 100 by the pressing unit. And, the ejection control unit may be configured as a kind of automated device for adjusting the ejection amount of the liquid phase by an external control signal.

The ultrasonic vibrator 300 vibrates the liquid material 600 injected from the liquid ejecting part 100 in a vibration cycle of ultrasonic waves. Due to the vibration of the ultrasonic vibrator 300, the liquid material 600 is evenly sprayed on the predetermined substrate 700. The ultrasonic vibrator 300 may be installed at the end of the liquid ejecting part 100 in which the liquid material 600 is sprayed onto the substrate 700.

The roller unit 400 evenly rolls the liquid material 600 onto the substrate 700 while rolling on the substrate 700 on which the liquid material 600 ejected by the liquid ejecting part 100 is coated. The roller unit 400 is formed of a plurality of rollers in a cylindrical shape to be arranged in a row to face the bottom, and may include a predetermined heating means to seat the liquid material on the substrate. In the case of a 40-inch panel squeeze, the number of rollers forming the roller part is about 10 pieces. In addition, the rollers 410, 420, and 430 roll on the substrate 700 and apply the liquid material 600, according to the uneven state of the protrusion 710 and the recess 720 of the substrate 700. As shown, the alignment is provided so as to deform.

Hereinafter, the operation principle of the present invention will be described with reference to FIGS. 2 and 3.

By the liquid ejection part 100 of the squeeze 500 according to the present invention, a liquid material 600 such as liquid MgO is sprayed onto a predetermined substrate 700. At this time, the ultrasonic vibrator 300 vibrates at the ultrasonic frequency of a fine vibration width to vibrate the liquid ejection unit 100. As a result, the ejection amount of the liquid material 600 is constant, so that the liquid material is evenly distributed on the substrate 700.

Evenly distributed liquid material on the substrate is evenly applied on the substrate by the roller portion 400 of the squeeze. Sometimes, even though the liquid material is not evenly distributed by the unevenness on the substrate, the rollers of the roller portion adjust the pressure applied to the substrate according to the unevenness on the substrate to distribute the liquid material evenly.

Since the squeeze 500 according to the present invention continuously performs the above-described operation while constantly moving, the liquid substance applied by the squeeze of the present invention is applied to the entire surface of the substrate.

Squeeze of the present invention has the effect that can be applied to a liquid material with little viscosity unlike the prior art. Accordingly, the liquid material used by the squeeze of the present invention does not need to be added an organic solvent, and thus has a higher purity than the liquid material used by the conventional squeeze. As a result, by using the squeeze of the present invention, it is possible to apply a high-purity liquid substance to the substrate, thereby improving the quality of the product.

For example, when the MgO protective film of the plasma display panel is applied by the squeeze of the present invention, the MgO liquid material used by the squeeze of the present invention is more organic solvent added than the MgO liquid material used by the conventional squeeze. Since it is not supported, there is an effect that a transparent MgO protective film can be formed.

In addition, when the liquid material is applied to the entire surface of the large area panel, the conventional squeeze necessarily uses a liquid material having a viscosity of a predetermined level or more, but the squeeze of the present invention can use a liquid material having almost no viscosity, There is also an effect that can further increase the homogeneity of the liquid material to be applied.

Claims (6)

In the printing squeeze, A liquid ejecting part filled with a liquid material to eject the liquid material; A spray control unit for controlling the amount of the liquid substance ejected from the liquid ejecting unit; And, A printing squeeze comprising an ultrasonic vibrator for vibrating the liquid material injected from the liquid ejecting portion in the vibration cycle of the ultrasonic wave. According to claim 1, wherein the blowing control unit A press unit for changing a diameter of a part of the liquid ejecting part by applying pressure to a part of the liquid ejecting part; And, Printing squeeze, characterized in that consisting of a pressure adjusting portion for adjusting the pressure applied by the pressing portion. The printing squeeze according to claim 1, wherein the ejection control unit is an automatic device for automatically adjusting the amount of the liquid substance ejected from the liquid ejection unit by an external control signal. The printing squeeze according to claim 1, wherein the ultrasonic vibrator is installed at the end of the liquid ejecting portion to which the liquid substance is injected. According to claim 1, wherein the printing squeeze rolls on the substrate coated with the liquid material ejected by the liquid ejecting portion while adding a roller portion to evenly apply the liquid material ejected by the liquid ejecting portion to a predetermined substrate Printable squeeze characterized in that the installation. 6. The printing squeeze according to claim 5, wherein a plurality of rollers are formed in a row in a row in a cylindrical shape.