KR101640868B1 - Simulation Apparatus for Nano-membrane Printing Process and Method of the Same - Google Patents

Abstract

The present invention relates to an apparatus and a method for simulating a nano thin film transfer process, and more particularly, to a device and a method for simulating a nano thin film transfer process in which the influence of adhesive property and process conditions on a material for transfer process, .

Description

Technical Field [0001] The present invention relates to a nano-membrane transfer process,

The present invention relates to an apparatus and a method for simulating a nano thin film transfer process, and more particularly, to a device and a method for simulating a nano thin film transfer process in which the influence of adhesive property and process conditions on a material for transfer process, .

There is a demand for a process of forming a pattern through contact between different materials in an imprint lithography process, a transfer process, and a printing process, which are used when manufacturing micro / nano-sized patterns and devices. In addition, a process for transferring a desired material (metal, polymer, ink, etc.) from one base material to another is indispensable.

At this time, the adhesion between the two materials to be contacted must be properly controlled to perform the process successfully.

Particularly, in order to manufacture a high-performance flexible electronic device and a display, it is necessary to separate a material and an element manufactured by a conventional semiconductor process from a substrate by contacting it with a stamp, and then transfer the material and the device to a flexible substrate. Also, in a printing process for manufacturing an electronic circuit in a continuous production process, a process of separating ink from a base material by contacting the stamp with a base material coated with a conductive ink, and then transferring the ink to a desired substrate is repeatedly performed.

In order to achieve successful printing, the adhesion characteristics between stamps, inks, base materials and substrates are very important, and not only materials but also process conditions such as contact pressure, speed and contact time have a great influence on the adhesive properties.

However, in order to solve this problem, in the past, optimum process conditions have been found by trial-and-error method with different materials and operating conditions. Therefore, much effort, time, and cost were required. Therefore, there is a need for a process simulation apparatus and method that finds optimum process conditions efficiently by examining the influence of the adhesion characteristics between the materials and the process conditions therefor.

Generally, to simulate the adhesive characteristics between a material and a material, a pair of nanotubes is coated with the same or different types of materials, and then a pair of coated nanotubes is contacted to simulate the adhesion characteristics between the materials.

In this case, even in the method of contacting a pair of thin films, it is not easy to bring a pair of nano thin films in parallel to each other in case of surface contact or line contact, so that errors may occur in simulation, .

Fig. 1 shows a schematic perspective view of a conventional tack simulator 10, and Fig. 2 shows a schematic cross-sectional view of a conventional tack characteristic simulator 10. In Fig. 3 is a partial schematic perspective view of a nano thin film adhered to the spheres 1 of a conventional tack simulator.

1, the simulation apparatus 10 includes a spherical surface 1 and a plane surface 2 and has a spherical surface 1 and a spherical surface 2 by using a contact portion P1 which is in point contact with the spherical surface 1 in contact with the spherical surface 1, And the nano thin film are attached to the contact surface of the flat surface 2, respectively.

That is, as shown in FIG. 2, the first thin film 3 coated with the first material is attached to the sphere 1, and the second thin film 4 coated with the second material, which is the same as or different from the first material, (3) and the second thin film (3) on the contact portion (P1) which are point-contacted by bringing the ball (1) into contact with the plane (2) 4) are simulated.

The conventional adhesion characteristic simulation apparatus 10 described above can be adhered to the plane 2 completely in the case of the second thin film 4 attached to the plane 2, In the case of the first thin film 3 attached to the sphere 1, wrinkles are generated in the first thin film 3 when it is attached to the sphere 1 without being completely adhered to the sphere. If the first thin film 3 is not completely adhered to the sphere 1, there is a high possibility that an error occurs in the adhesion characteristic test.

Therefore, in an apparatus for simulating the adhesion characteristics of a pair of nano-thin films, it is required to develop a technique capable of simulating the adhesion characteristic through point contact in a state where each thin film is completely in close contact with the simulation apparatus.

Furthermore, it is required to develop a technique that can combine various kinds of samples with each other to simulate the adhesive characteristics according to each combination in a short time.

Korean Patent No. 10-1049396 (July 8, 2011)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a nano- The present invention provides a nano thin film transfer process simulation apparatus and method capable of simulating the adhesion characteristic of a nano thin film coated with a Si material.

A plurality of thin films of materials having different characteristics or materials having the same thickness are attached to each of the rolls and a plurality of thin films of the same material having different properties are attached to each of the rolls, And a transfer process simulation apparatus and method.

The nano thin film transfer process simulation apparatus of the present invention comprises: a first roller arranged in the x direction in the axial direction; A second roller disposed on the other side of the first roller in the z direction orthogonal to the x and y directions of the first roller, with the y direction having the predetermined angle slope in the x direction as the axial direction; A first thin film attached to an outer surface of the first roller; A second thin film attached to an outer surface of the second roller; And first rotating means for rotating the first roller or the second roller in the z direction so that the first thin film and the second thin film are in contact with each other; .

At this time, a plurality of the first thin films are spaced apart from each other along the x direction on the first roller, a plurality of the second thin films are disposed on the second roller along the y direction, The apparatus includes: second rotating means for rotating the first roller in the y direction; And third rotating means for rotating the second roller in the x direction; .

A plurality of the first thin films are disposed on the first roller in the circumferential direction, the second thin films are spaced apart from each other along the circumferential direction on the second roller, and the simulation device A first rotating means for rotating the first roller about the rotation axis in the x direction; And second rotating means for rotating the second roller in the y direction about a rotational axis; .

The plurality of first thin films or the plurality of second thin films may be made of different materials, respectively, or the plurality of first thin films or the plurality of second thin films may have different thicknesses.

In addition, the simulation apparatus may further include: an optical system that is disposed at a predetermined distance from one side of the z-direction of the contact portion in contact with the first thin film and the second thin film to observe the contact portion; And a load cell spaced apart from the other side in the z direction of the contact portion and measuring a load applied to the contact portion; And the optical system, the contact portion, and the load cell are arranged in a straight line.

A method of simulating a nano thin film transfer process simulation apparatus, comprising: disposing a second roller on the other side in the z direction of a first roller; Attaching a first thin film to the first roller and attaching a second thin film to the second roller; Contacting the first thin film and the second thin film by rotating the first roller or the second roller in the z direction; Measuring an adhesion characteristic between the first thin film and the second thin film through an optical system and a load cell; .

In addition, the simulation method may further include: disposing a plurality of first thin films on a circumferential direction on the first roller; Spacing a plurality of second thin films along the circumferential direction on the second roller; Rotating the first roller in the y direction, and then contacting the first thin film and the second thin film adjacent to the first thin film; And rotating the second roller in the x direction, and then contacting the first thin film and the second thin film adjacent to the second thin film; .

In addition, the simulation method may further include: disposing a plurality of first thin films on the first roller along the x direction; Disposing a plurality of second thin films on the second roller along the y direction; Contacting the first thin film and the second thin film adjacent to the first thin film after rotating the first roller with the rotation axis in the x direction; And rotating the second roller about the rotation axis in the y direction to contact the first thin film and the second thin film adjacent to the second thin film; .

The plurality of first thin films or the plurality of second thin films may be made of different materials, respectively, or the plurality of first thin films or the plurality of second thin films may have different thicknesses.

The apparatus and method for nano thin film transfer process simulation according to the present invention as described above simulate the adhesion characteristics between thin films through point contact so that the contact shape is constant regardless of the parallel alignment between thin films, .

Further, since the thin film is attached to a cylindrical roll and simulated, it is possible to minimize the occurrence of deformation and the occurrence of wrinkles when the thin film is attached, thereby further reducing the possibility of test errors.

Various kinds of samples can be combined by attaching thin films of various materials or thin films of various thicknesses along the rotation direction of the rolls or the axial direction of the rolls and by rotating the rolls or moving the rolls in the axial direction, Can be measured through a single test.

1 is a schematic perspective view of a conventional transfer process simulator
2 is a schematic cross-sectional view of a conventional transfer process simulator
3 is a schematic view of a nano thin film attached to a sphere in a conventional transfer process simulation
4 is a schematic perspective view of a transfer process simulator according to an embodiment of the present invention.
5 is a schematic front view of a transfer process simulator according to an embodiment of the present invention
Figure 6 is a schematic view of a nanofiltration membrane attached to a roll according to one embodiment of the present invention.
7 and 8 are schematic diagrams of a transferring process simulation method according to an embodiment of the present invention

Before describing the present invention, the y direction is defined as a direction inclined at a certain angle in the x direction, and the z direction is defined as a direction perpendicular to the x direction and the y direction.

(Hereinafter referred to as "simulator") according to an embodiment of the present invention is a device for simulating a transfer process of a nano thin film (hereinafter referred to as a " simulator ") in which a sample nano thin film is attached to a pair of rolls, a pair of rolls are arranged crossing each other, Of the nanotubes was point-contacted. Accordingly, the simulator of the present invention simulates the adhesion characteristics between the thin films through the point contact, so that the contact shape is constant regardless of the parallel alignment between the thin films, thereby reducing the possibility of test errors.

In addition, since the cylindrical roll is applied to the simulator and the nano thin film adheres to the outer surface of the roll, deformation or wrinkling of the nano thin film does not occur at the time of adhering, thereby further reducing the possibility of test error.

Further, a plurality of thin films having different thicknesses or different thicknesses are attached to a pair of rolls with a predetermined distance therebetween, and the adhesion test according to the combination of various thin films is performed at one time by rotating the rolls or moving the rolls in the axial direction There is a characteristic that the simulation of the adhesion characteristic of various combinations can be performed in a short time.

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

FIG. 4 is a schematic perspective view of a simulator 100 according to an embodiment of the present invention, and FIG. 5 is a front view of a simulator 100 according to an embodiment of the present invention.

Referring to FIG. 4, the simulator 100 includes a first roller 110, a second roller 120, and a first rotating means (not shown). The first roller 110 may be cylindrical. The first roller 110 may be disposed in the x direction as the axial direction. Also, the second roller 120 may be cylindrical. The second roller 110 may be disposed in the y direction as the axial direction. At this time, the second roller 120 may be disposed on the other side in the z direction of the first roller 110. In addition, the simulator 100 includes first rotating means for reciprocating linear motion of the first roller 110 in the z direction. In the simulator 100 having the above-described structure, when the first roller 110 rotates to the other side in the z direction through the first rotating means, the other side of the z direction of the first roller 110 and the z direction of the second roller 120 The contact portion P10 is brought into point contact when one side is in contact. The first roller 110 and the second roller 120 are in contact with each other by the z-directional rotation of the first roller 110. However, the first roller 110 may be provided on the second roller 120 It is obvious that the second roller 120 may be rotated in one direction in the z direction so that the first roller 110 and the second roller 120 may be connected. The detailed configuration of the simulator 100 having the above-described configuration as a basic configuration will be described in detail with reference to FIG.

5, the simulator 100 includes a first roller 110, a second roller 120, a load cell 130, an optical system 140, a mount 150, a first thin film 210, (220).

1, the first roller 110 includes a first body 111 coupled to the first rotation axis 112 and the first rotation axis 112 so as to be rotatable in the x direction, do. The first thin film 210 to be tested for adhesion is attached to the other side of the first body 111 in the z direction. The first thin film 210 can be formed by forming a test target material in a thin film form or coating the test target material on the thin film.

The second roller 120 includes a second body 121 coupled to the second rotation axis 122 and the second rotation axis 122 so as to be rotatable in the y direction. The lower side of the second rotation shaft 122 may be fixed to the horizontal support 125. The horizontal support 125 may be slidably coupled to the platform 150 along the y direction.

A second thin film 220 to be tested for adhesion is attached to one side surface of the second body 121 in the z direction. The second thin film 220 can be formed by forming the test subject material into a thin film or coating the test subject material on the thin film. The second thin film 220 may be formed of a different material from the first thin film 210 or may have a thickness different from that of the first thin film 210.

When the first and second rollers 110 and 120 are rotated in the z direction to come into contact with each other, the contact portion P10 where the first and second thin films 210 and 220 are in contact with each other, So that the adhesion characteristic between the first thin film 210 and the second thin film 220 is simulated.

The optical system 140 is disposed at a certain distance on one side of the contact portion P10 in the z direction so that the first thin film 210 and the second thin film 220 observe the adhesive property when they are in contact with each other. The load cell 130 is provided on the other side in the z direction of the contact portion P10 so as to abut the other side in the z direction of the second rotation shaft 122 and the first roller 110 and the second roller 120 abut against each other. The adhesive force between the first thin film 210 and the second thin film 220 is simulated by measuring the load. The load cell 130 may be provided on the upper surface of the holder 150.

At this time, the contact portion P10, the optical system 140, and the load cell 130 may be arranged in a straight line along the z direction. This is because the load cell 130 must be placed in a straight line with the contact portion P10 when the first roller 110 and the second roller 120 are in contact with each other and a precise load measurement can be performed. P10 and the load cell 130 are arranged on a straight line.

FIG. 6 is a schematic perspective view showing a state in which a first thin film 210 having various materials or various thicknesses is attached to a first roller 110 according to an embodiment of the present invention.

The simulator 100 of the present invention is configured as follows to constitute a combination of thin films having various materials or thicknesses, which is one of the other features of the present invention, and to simulate the adhesion characteristics of thin films having various combinations in a short time.

As shown in the figure, a plurality of first thin films 210 may be attached to the outer surface of the first body 111. The plurality of first thin films 211, 212, 213, and 214 may be spaced apart from each other by a predetermined distance along the axial direction of the first body 111. The plurality of first thin films 210 may be spaced apart from each other by a predetermined distance along the circumferential direction of the first body 111. At this time, the plurality of first thin films 210 may be formed of different materials or may have different thicknesses.

Although not shown in the figure, a plurality of second thin films 220 may be attached to the outer surface of the second body 121 as well. The plurality of second thin films 220 may be spaced a predetermined distance along the axial direction of the second body 121. The plurality of second thin films 220 may be spaced apart from each other along the circumferential direction of the second body 121. At this time, the plurality of second thin films 220 may be formed of different materials or may have different thicknesses.

The first roller 110 and the second roller 120 configured as described above simulate the adhesion characteristics of the first thin film 210 and the second thin film 220 in different combinations according to their respective rotational or axial rotations .

FIG. 7 and FIG. 8 are schematic flowcharts of a simulation method of the transfer process simulator 100 according to an embodiment of the present invention. [0040] The adhesion characteristic simulation according to the above-described various combinations of configurations will be described in more detail.

The first roller 110 is provided with a first rotating means capable of rotating the first body 111 in the x-axis direction. The first roller 110 has a second rotation Means.

The second roller 120 is provided with a second rotating means capable of rotating the second body 121 in the y axis direction and a second rotating means for rotating the second body 121 in a reciprocating linear motion in the x- 2 rotating means.

When the first body 111 is rotated through the above-described structure, the first thin film 210 attached to the first body 111 along the circumferential direction of the first body 111, It is possible to simulate the adhesion characteristics of the first thin film 210 and the second thin film 220 in various combinations by contacting the thin film 220.

In addition, when the first body 111 linearly moves in the y-direction, the second thin film 210 attached to the first body 111 along the axial direction of the first body 111 may have a second It is possible to simulate the adhesion characteristics of the first thin film 210 and the second thin film 220 in various combinations by contacting the thin film 220.

When the second body 121 rotates, the first thin film 210 attached to the first body 111 is attached to each of the plurality of second thin films 220 attached along the circumferential direction of the second body 121, So that the adhesion characteristics of the first thin film 210 and the second thin film 220 in various combinations can be simulated.

When the second body 121 is linearly moved in the x direction, the second thin film 210 attached to the first body 111 along the axial direction of the second body 121, 1 thin film 210 are in contact with each other to simulate the adhesion characteristics of the first thin film 210 and the second thin film 220 in various combinations.

Even if the first body 111 and the second body 121 are adhered to each other by the axial movement as described above, the contact portion 110, the optical system 140, and the load cell 130 are always aligned with the first body 111 And the second body 121 are moved.

The first roller 110 and the second roller 120 are disposed such that the load cell 130 is positioned on the contact portion P10 where the first roller 110 and the second roller 120 abut each other, , The load cell 130 and the optical system 140 are fixedly arranged on the z direction so that the first roller 110 and the second roller 120 are positioned so that the load cell 130 and the contact portion P10 are aligned on the z- The optical system 140 and the contact P10 may be automatically positioned in the z direction.

Hereinafter, the operation of the present invention will be described in detail.

A step of disposing a second roller whose axial direction is the y direction on the other side of the z-direction of the first roller whose axial direction is the x-direction is performed. In this case, the first roller is provided with the first rotating means so as to be rotatable in the x direction by the rotation axis, and has the first rotating means for linearly reciprocating along the z direction. The second roller Means. The second roller is provided with the second rotating means so as to be rotatable in the y direction by the rotation axis, and is provided with the third rotation means for linearly reciprocating along the x direction.

Next, a step of attaching the first thin film to the first roller and attaching the second thin film to the second roller is performed. At this time, the second thin film may be formed of a material different from the first thin film, and may be formed of a thin film having the same thickness as the first thin film, which is the same material as the first thin film.

Next, the step of bringing the first thin film and the second thin film into contact is performed by rotating the first roller in the z direction. At this time, the contact portions of the first thin film and the second thin film are point-contacted so that accurate adhesion characteristic simulation can be performed without considering the planarity of the first thin film and the second thin film.

Next, the simulation method of the present invention is completed by performing the step of measuring the adhesive property between the first thin film and the second thin film through the optical system and the load cell.

In this case, the following method may be added to the simulation method so as to simultaneously perform the adhesion characteristics of a plurality of thin films having various materials and thicknesses.

First, a plurality of first thin films are spaced apart along the circumferential direction on the first roller, and a plurality of first thin films are spaced apart from each other along the x direction. At this time, the plurality of first thin films may be made of different materials or may have different thicknesses.

Next, a plurality of second thin films are spaced apart along the circumferential direction on the second roller, and a plurality of second thin films are spaced apart along the y direction on the second roller. At this time, the plurality of second thin films may be made of different materials or may have different thicknesses.

Rotating the first roller in the y direction, and then contacting the first thin film and the second thin film adjacent to the first thin film; Rotating the second roller in the x direction, and then contacting the first thin film and the second thin film adjacent to the second thin film; Contacting the first thin film and the second thin film adjacent to the first thin film after rotating the first roller with the rotation axis in the x direction; And rotating the second roller about the rotation axis in the y direction to contact the first thin film and the second thin film adjacent to the second thin film; Are sequentially or randomly performed to simulate the adhesion characteristics of the first thin film and the second thin film in various combinations.

The technical idea should not be construed as being limited to the above-described embodiment of the present invention. 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. Accordingly, such modifications and changes are within the scope of protection of the present invention as long as it is obvious to those skilled in the art.

100: simulator
110: first roller 111: first body
112: first rotating shaft
120: second roller 121: second body
122: second rotation shaft 125: horizontal support
130: Load cell
140: Optical system
150: Cradle
P10: Contact
210: first thin film 220: second thin film

Claims (11)

a first roller disposed axially in the x direction;
A second roller disposed on the other side of the first roller in the z direction orthogonal to the x and y directions of the first roller, with the y direction having the predetermined angle slope in the x direction as the axial direction;
A first thin film attached to an outer surface of the first roller;
A second thin film attached to an outer surface of the second roller; And
First rotating means for rotating the first roller or the second roller in the z direction so that the first thin film and the second thin film come into contact with each other; ≪ / RTI >
Wherein the first thin film and the second thin film simulate an adhesive property in a state of point contact through the first rotating means,
Wherein the first thin film and the second thin film are made of materials different from each other.
The method according to claim 1,
Wherein a plurality of the first thin films are disposed on the first roller along the x direction and the second thin films are spaced apart from each other along the y direction on the second roller,
The simulation apparatus includes:
Second rotating means for rotating the first roller in the y direction; And
A third rotating means for rotating the second roller in the x direction;
Wherein the nano thin film transfer process simulation apparatus comprises:
The method according to claim 1,
Wherein a plurality of the first thin films are disposed on the first roller in the circumferential direction and spaced apart from each other along the circumferential direction on the second roller,
The simulation apparatus includes:
A first rotating means for rotating the first roller with the rotation axis in the x direction; And
Second rotating means for rotating the second roller in the y direction about the rotational axis;
Wherein the nano thin film transfer process simulation apparatus comprises:
The method according to claim 2 or 3,
Wherein the plurality of first thin films or the plurality of second thin films are made of different materials from each other.
The method according to claim 2 or 3,
Wherein the plurality of first thin films or the plurality of second thin films have different thicknesses.
The method according to claim 1,
The simulation apparatus includes:
An optical system disposed at a predetermined distance from the first side of the contact portion where the first thin film and the second thin film are in contact with each other to observe the contact portion; And
A load cell arranged at a predetermined distance from the other side of the contact portion in the z direction to measure a load applied to the contact portion; / RTI >
Wherein the optical system, the contact portion, and the load cell are disposed on a straight line.
A simulation method of a nano thin film transfer process simulation apparatus according to claim 1,
Disposing a second roller on the other side of the z-direction of the first roller;
Attaching a first thin film to the first roller and attaching a second thin film to the second roller;
Contacting the first thin film and the second thin film by rotating the first roller or the second roller in the z direction;
Measuring an adhesion characteristic between the first thin film and the second thin film through an optical system and a load cell; , ≪ / RTI &
Wherein the first thin film and the second thin film simulate an adhesive property in a state of point contact through the z direction rotation,
Wherein the first thin film and the second thin film are made of materials different from each other.
8. The method of claim 7,
In the simulation method,
Spacing a plurality of first thin films along a circumferential direction on the first roller;
Spacing a plurality of second thin films along the circumferential direction on the second roller;
Rotating the first roller in the y direction, and then contacting the first thin film and the second thin film adjacent to the first thin film; And
Rotating the second roller in the x direction, and then contacting the first thin film and the second thin film adjacent to the second thin film;
Wherein the nano thin film transfer process simulation method comprises:
8. The method of claim 7,
In the simulation method,
Disposing a plurality of first thin films on the first roller along the x direction;
Disposing a plurality of second thin films on the second roller along the y direction;
Contacting the first thin film and the second thin film adjacent to the first thin film after rotating the first roller with the rotation axis in the x direction; And
Rotating the second roller in the y direction by a rotation axis, and then contacting the first thin film and the second thin film adjacent to the second thin film;
Wherein the nano thin film transfer process simulation method comprises:
10. The method according to claim 8 or 9,
Wherein the plurality of first thin films or the plurality of second thin films are made of different materials, respectively.
10. The method according to claim 8 or 9,
Wherein the plurality of first thin films or the plurality of second thin films have different thicknesses.

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