KR101139468B1 - A ink-jet header with screw type - Google Patents

Abstract

According to the present invention, the gap between the nozzle part and the screwed ground part can be finely adjusted as the screw is moved up and down by screw rotation, so that the exact distance value between the meniscus of the inkjet header having different environmental conditions and the ground electrode can be adjusted. The invention relates to a screw-type inkjet header that can be found to enable more precise circuit wiring patterning.

Printed Electronics, Printed Electronics, Electro-hydrodynamics (EHD) Heads, Inkjet Heads, Electrostatic Heads, Silicon Heads

Description

Screw Type Inkjet Headers {A INK-JET HEADER WITH SCREW TYPE}

The present invention relates to an inkjet header for fine circuit printing of a substrate material, and more particularly, to a screw type inkjet header for printing metal nanoparticles on a circuit board, particularly a flexible substrate material.

In general, a circuit board is formed through photolithography (lithography) through the process of exposing, etching, depositing, and processing electronic wiring. However, with the development of complex printing process and equipment technology, the circuit board is directly patterned on various substrates. Therefore, a technology for mass production of next generation printed electronic devices and products such as solar cells, RFID, flexible displays, and smart packages has been proposed.

The printed electronics (printed electronics) method is a nano-patterning technology for forming a fine electronic circuit by printing metal nanoparticles on a flexible substrate (various flexible substrate material).

In the above method, the inkjet header patterns the wiring on the circuit board by discharging the ink in which the metal nanoparticles are dissolved. The ink discharging technique and the technique of dropping the discharged ink to the correct point are most effective in reducing the defect rate of the circuit. Since it is an important precision technology, various inkjet header technologies have been proposed for this purpose.

In particular, the distance from the meniscus formed at the end of the chamber to the ground at the bottom of the inkjet header is a key to determining the drop of ink. Therefore, the distance between the chamber and the bottom constituting the inkjet header should be more precisely controlled.

An object of the present invention for solving the above problems, in adjusting the distance between the nozzle portion and the ground portion, the screw coupled to the nozzle portion and screwed to the ground as the ascending and descending by rotating the screw is finely adjusted To provide a type of inkjet header.

In addition, the object of the present invention, by forming the n through holes on the side of the ground portion, the screw type to be observed while rotating the lower portion by an angle of (360 / n) to check whether the ink falls from the meniscus To provide an inkjet header.

According to the present invention according to the problem to be solved in the inkjet header, the glass capillary penetrating path is formed along the longitudinal direction so as to insert the glass capillary, the glass capillary tube is inserted in the lower microelectrode connected to the upper electrode plate It is accommodated in the center, the ink is received in the glass capillary through a branched ink circulation path extending to both sides vertically from the glass capillary passage, the lower outer surface of the cylindrical ink circulation forming a screw Wealth; The inner side is formed of a screw to engage with the outer surface screw of the ink circulating portion, the nozzle hole is formed in the center of the lower surface to allow the glass capillary tube to pass through the nozzle hole and to form a screw on the outer side A cylindrical nozzle portion; A screw is formed on the inner side and screwed to the nozzle part. A circular ground plate is attached to the lower end thereof to be polarized together with the microelectrode so that the micro electrode and the circular ground plate move upward and downward through the screw rotation from the nozzle part. It is achieved by a screw type inkjet header, characterized in that it consists of a cylindrical grounding portion which allows the ink to form a meniscus at the bottom of the glass capillary while adjusting the distance between them.

In addition, the ink circulation path and the ink supply unit for supplying the ink to the glass capillary through the glass capillary passage; It is preferable that the ink discharge port is formed at a position lower than a predetermined height so that the supplied ink is discharged without being flowed back to the ink supply portion, and discharges the supplied ink.

In addition, according to the present invention, the nozzle portion is laminated with a silicon disc on the bottom of the bottom, the hole having the same dimensions as the nozzle hole is formed so that the glass capillary tube penetrates the center of the silicon disc, the ink circulation portion and the nozzle portion It is preferable that the lower end of the ink circulating portion presses the silicon disc by the strong coupling through the screw, and the glass capillary side portion penetrating the nozzle hole is in watertight contact with the hole of the silicon disc by the pressing of the silicon disc. .

Further, according to the present invention, to observe the meniscus state of the glass capillary end, the ground portion is formed with a plurality of through-hole ink droplet observation portion formed on the side on a predetermined distance from the lower end, while rotating the ground portion from the nozzle portion As the height is finely moved, it is preferable to check the presence or absence of the meniscus through the ink droplet observation unit.

In the screw type inkjet header of the present invention by the above-mentioned means for solving the above problem, the interval between the nozzle portion and the screwed ground portion ascending and descending by rotation can be finely adjusted, so that the pulse applied to the electro, etc. Likewise, the environmental conditions can find the exact distance between the meniscus of the different inkjet header and the ground electrode, thereby enabling more accurate circuit wiring patterning.

Hereinafter, an embodiment of a screw type inkjet header of the present invention will be described in more detail with reference to the accompanying drawings.

As shown in FIG. 1, the screw type inkjet header of the present invention includes an ink circulating part 10, a nozzle part 20, a grounding part 30, and a microelectrode coupling part 40.

The ink circulation part 10 is a cylindrical shape in which a glass capillary passage 11 is formed so that a glass capillary tube (17 in FIG. 3) is inserted therein.

One side of the glass capillary is inserted into the glass capillary passage and the lower side is exposed to pass through the nozzle hole from the glass capillary passage.

A side of the ink circulation part 10 is formed to protrude from the branched ink circulation path extending vertically from both sides of the glass capillary passage 11, one side of the ink supply port 12 is supplied ink The other side becomes the ink discharge port 13 through which ink is discharged.

At this time, the ink discharge port 13 is formed at a lower position than the ink supply unit 12 so that the supplied ink flows to the ink discharge port 13 without flowing back to the ink supply unit 12.

The ink circulation portion 10 is formed with a screw on the upper and lower outer surface of the ink circulation passage.

The upper side 14 of the ink circulating portion 10 is coupled to the micro-electrode coupling portion 40 to be described later, the lower side 15 to be screwed to the nozzle unit 20 to be described later do.

The nozzle unit 20 is formed in a cylindrical shape, and its inner side 21 is formed with a screw so as to be coupled to the lower side 15 of the ink circulation unit 10.

The nozzle unit 20 has a nozzle hole 25 formed in the center of the lower surface thereof, and the glass capillary tube penetrates through the nozzle hole 25.

In addition, the nozzle unit 20 is laminated with a silicon disc 23 on the bottom of the bottom, the hole 24 having the same dimensions as the nozzle hole 25 is formed in the center of the silicon disc 23.

Therefore, the lower end of the ink circulation portion 10 presses the silicon disc 23 by the strong coupling through the screw of the ink circulation portion 10 and the nozzle portion 20, and penetrates the nozzle hole 25. The glass capillary tube is brought into watertight contact with the hole 24 of the silicon disc 23 by pressing the silicon disc 23 and is sealed to prevent ink from flowing out of the nozzle hole.

In addition, the nozzle part 20 forms a screw on the entire outer side surface 22 thereof, and is screwed with a screw formed on the inner surface 31 of the ground part 30.

The ground portion 30 is cylindrical and has a screw formed on its inner surface to accommodate the nozzle portion 20 and is screwed together.

Therefore, the ground portion 30 is able to move up and down finely from the nozzle portion through a screw rotation with the nozzle portion 20.

The ground portion 30 has a hole 32 formed in the center of the lower surface, so that the metal particles fall from the ink in the meniscus state.

In addition, the ground portion 30 has a ground plate 33 is attached to the outer bottom.

The ground electrode is a donut-shaped metal plate having through holes having the same dimensions as the holes 32 in the center.

In addition, the ground portion 30, the ink droplet observation portion 34 is formed on the side on a predetermined distance from the lower end.

The ink droplet observation unit 34 is a through hole formed on the side of the ground portion and is for observing the meniscus state.

The microelectrode coupler 40 is attached to a conveyer, and has a cylindrical shape having an upper disk and a side surface perpendicular to the disk.

Silicon plates 41 and 42 are positioned on an upper end of the microelectrode coupling unit, and a microelectrode plate 43 is interposed between the upper and lower silicon plates.

The microelectrode plate 43 is connected to the outside through the silicon plates 41 and 42 so that one side is connected to the power supply, and the other side is connected to the microelectrode 44 to supply power from the power supply. The current flows through the fine electrode 44.

The microelectrode 44 is accommodated in the glass capillary, and when a current flows, the metal particles of the ink filled in the glass capillary are polarized.

Figure 2 shows an assembly cross section of the screw type inkjet header of the present invention.

As shown in the figure, the lower side of the inside of the micro-electrode portion 40 has a screw is screwed with the upper surface 14 of the ink circulation (10).

Therefore, the microelectrode of the microelectrode portion 40 is coupled in a state accommodated in the glass capillary inserted into the glass capillary passage of the ink circulation portion 10.

The microelectrode portion 40 and the ink circulating portion 10 are screwed together, and the screw and ink circulating portion 10 inside the nozzle portion 20 in a state where the glass capillary is exposed to the lower end of the ink circulating portion 10. The lower screw is engaged by screwing.

At this time, the exposed glass capillary passes through the nozzle hole and is exposed to the lower end of the nozzle unit 20.

In screwing the nozzle unit 20 and the ink circulating unit 10, when the lower end of the ink circulating unit 10 and the silicon disc of the nozzle unit 20 come into contact with each other through screwing, a more firm screwing is performed. The silicon disc is engaged with the outer lower end of the ink circulating part 10 and the inner lower end of the nozzle part 20 to expand laterally.

Therefore, the glass capillary tube penetrating the center of the silicon disc of the nozzle unit 20 is tightly coupled to the silicon disc by side expansion of the silicon disc.

As described above, in the state in which the ink circulation unit 10 and the nozzle unit 20 are coupled, the inner screw of the grounding unit 30 is engaged with the outer screw, and the grounding unit 30 of the The ink droplet observation unit allows the inside of the glass capillary to be observed.

At this time, the ground portion 30 is able to move up and down by a fine interval while rotating the screw, and at the same time to observe the meniscus state on the glass capillary inside while plunging through a plurality of ink droplet observation unit. .

Hereinafter, a detailed description of the operation of the inkjet header will be mentioned.

The micro feeder driven by the step motor is controlled according to the input path of the controller device and finely moved in a predetermined pattern so that the inkjet header attached to the feeder is positioned on the substrate and filled in the inkjet header. The ink is sprayed through the nozzle of the ink jet header to form a circuit pattern on the substrate.

At this time, the ink is filled with a mixture of metal (eg silver) and solvent (eg water or ethanol).

First of all, the ink made by dissolving the metal salt, metal or ceramic component to be patterned in pure water is introduced through the ink supply port so that the metal ink is contained in the glass capillary.

One end is supplied with power from the other end of the microelectrode impregnated with the ink so that a predetermined charged particle is applied to the ink contained in the glass capillary.

As a result, high voltage flows through the microelectrode, and the metal ink generates fine charged particles having the same polarity as the microelectrode.

At the same time, current flows to the ground plate of the ground portion 30.

In this state, the ink discharged through the glass capillary forms a meniscus and becomes confined to the lower end of the nozzle hole, and concentrates particles from the meniscus ink due to the electrostatic attraction of the opposite polarity flowing through the electrode plate of the ground portion. The particles with reduced furnace diameter are attached to the substrate.

In addition, when the meniscus is not formed at the glass capillary end, the ground portion 30 is slowly screw-rotated from the nozzle portion 20 to adjust the gap between the glass capillary end and the ground plate, and through the ink droplet observation portion. Observe whether a meniscus is formed at the glass capillary tip inside.

1 is an exploded cross-sectional view of each part of the screw-type inkjet header of the present invention;

2 is an assembled state cross-sectional view of the component of FIG. 1;

3 is an operating state diagram in the assembled state of FIG.

* Detailed Description of Drawings *

10: ink circulation portion 20: nozzle portion

30: ground portion 40: fine electrode coupling portion

Claims (4)

delete A glass capillary passage 11 is formed along the length of the glass capillary to insert the glass capillary tube, and the microelectrode connected to the upper electrode plate is accommodated in the glass capillary tube inserted into the lower portion of the glass capillary tube. (11) vertically extending to both sides through the branched ink circulation path to receive the ink in the glass capillary, the lower outer surface of the cylindrical ink circulation portion 10 forming a screw; The inner side 21 is formed of a screw to engage with the outer surface screw of the ink circulating portion 10, and a nozzle hole 25 is formed in the center of the lower surface of the ink circulation part 10 so that the glass is formed through the nozzle hole 25. A cylindrical nozzle portion 20 through which the capillary tube penetrates and forms a screw on an outer side thereof; Screws are formed on the inner side to be screwed to the nozzle unit 20, and a circular ground plate is attached to the lower end thereof so as to be polarized together with the microelectrode, and move up and down through the screw rotation from the nozzle unit. In the screw type inkjet header, characterized in that it consists of a cylindrical ground portion 30 to adjust the distance between the circular ground plate, the ink to form a meniscus at the bottom of the glass capillary, The ink circulation path and the ink supply unit for supplying the ink to the glass capillary through the glass capillary passage; It is characterized in that the ink discharge port 13 is formed in a position lower than the ink supply portion 12 position so that the supplied ink is discharged without flowing back to the ink supply portion 12 to discharge the supplied ink Screw type inkjet header. 3. The method of claim 2, The nozzle unit 20 has a silicon disc 23 laminated on the bottom of the bottom, and the hole 24 having the same dimensions as the nozzle hole 25 is formed so that the glass capillary tube penetrates the center of the silicon disc 23. The lower end of the ink circulating portion 10 presses the silicon disc 23 by the strong coupling through the screw of the ink circulating portion 10 and the nozzle portion 20, and the nozzle hole 25 is opened. A screw-type inkjet header, characterized in that the penetrating glass capillary side portion is in watertight contact with the hole (24) of the silicon disc (23) by the pressing of the silicon disc (23). 3. The method of claim 2, In order to observe the meniscus state of the glass capillary end, the ground portion 30 is formed with a plurality of through-hole ink droplet observation portion 34 formed on the side surface at a predetermined distance from the lower end, so that the ground portion rotates from the nozzle portion. Screw type inkjet header, characterized in that to check the presence or absence of the meniscus through the ink droplet observation portion 34 as the height moves finely.

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