KR100719999B1 - Silicon applying system and method - Google Patents

Abstract

The present invention relates to a silicon coating apparatus and method, wherein a compressed air line having an electronically controlled opening / closing valve (V1) interposed therebetween, one end of which is connected to the pneumatic source and the other end of which is circulated to the inside of the storage container (1). A silicone liquid supply unit 10 which receives the pneumatic pressure by (2) and discharges the silicon liquid stored therein by the pneumatic pressure to the outside; A silicon flow passage 410 which is supplied / rejected from the silicon liquid supply unit 10 via a conduit L1 and is circulated / blocked by a needle valve type valve built therein to inject silicon liquid onto a substrate; A nozzle unit 20 in which a nozzle hole 420 is formed; Compressed air flows through the compressed air flow path 240 and the compressed air flow path 430 formed in the nozzle unit 20 so as to be distributed to each other via the conduit L2 having the electronic control valve V2 interposed therebetween. The compressed air is supplied to a bore 340 which supplies and opens and closes the needle valve built in the nozzle unit 20 via a conduit L3 having an electronically controlled opening / closing valve V3 interposed therebetween. And a control unit 30 connected to a pneumatic source for supplying or discharging the compressed air, wherein the compressed air flow path 430 is disposed adjacent to the outer circumference of the nozzle hole 420. have.

Silicone liquid, needle valve, nozzle part, control part, silicone liquid supply part

Description

Silicon coating system and method

1 is an overall conceptual view of the silicone coating device of the present invention,

2 is a detailed cross-sectional view of the nozzle unit of FIG. 1, and

3 is a flow chart illustrating a method of controlling the silicon coating device of FIG.

The present invention relates to a silicon coating apparatus and method, and more particularly to an apparatus and method for coating a substrate with silicon.

There is a soldering part on the substrate that fixes the electrical connection. The board is coated with silicon to insulate this soldering site from the outside.

The method of coating the substrate with silicon includes a dip coating method for depositing and coating a substrate on a container containing high viscosity silicon, and a nozzle coating method for coating the substrate through a nozzle. This immersion coating method requires a lot of coating liquid, the thickness of the coating layer is not only constant, there is a disadvantage that the device for performing the immersion coating is complicated.

In addition, the immersion coating method is a natural drying method and a hot air drying method is adopted for the curing of the coating layer, at this time, the natural drying method takes a long time for curing, the hot air drying method is damaged of the components weak to heat mounted on the substrate May cause.

Therefore, nowadays, the nozzle coating method is adopted instead of the deposition coating method having such a disadvantage.

However, the nozzle coating method is a method in which the silicon liquid is applied to the substrate by supplying the silicone liquid to the nozzle by using pneumatic pressure and discharging the silicone liquid out of the nozzle by the force of the high pressure, but the silicone liquid is highly viscous and thus discharged out of the nozzle. Since the liquid is not ejected and is discharged in a nearly straight shape, there is a problem that a large amount of application distance is required on the substrate for the nozzle to coat the surface of the substrate.

Therefore, in order to solve this problem, high viscosity silicone liquid has to be injected through the nozzle, but a nozzle coating apparatus has not yet been developed to perform such a method, and even if highly developed, the highly viscous silicone liquid can be used to spray the nozzle. When the discharge is stopped, but the discharge is stopped, the cone liquid at the tip of the nozzle is hardened in contact with the outside air to block the nozzle hole, there was a problem that the discharge through the next nozzle is impossible.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a silicone coating apparatus and method capable of spraying a highly viscous silicone liquid through a nozzle.

In order to achieve the above object, the present invention provides a pneumatic air supply by means of a compressed air line interposed between an electronically controlled opening and closing valve, one end of which is connected to the pneumatic source, and the other end of which is circulated to the inside of the reservoir. The silicon liquid supply unit for discharging the silicone liquid stored therein to the outside; A nozzle unit having a silicon flow passage and a nozzle hole formed by a needle valve type valve built therein to receive the silicon liquid discharged from the silicon liquid supply unit through a conduit and inject the silicon liquid onto a substrate; And a compressed air flow path and a compressed air flow path that are circulated to each other through the conduit with an electronically controlled open / close valve interposed therebetween, and a conduit having an electronically controlled open / close valve interposed therebetween. And a control unit connected to a pneumatic source for supplying compressed air or discharging the compressed air to a bore capable of inducing opening and closing of the needle valve embedded in the nozzle unit via the compressed air flow path. It is arrange | positioned adjacent to the outer periphery of the said nozzle hole.

Hereinafter, a silicon coating apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

In Fig. 1, the silicone coating device of this embodiment is indicated as a whole by reference numeral 100.

The silicone coating device 100 is connected to a pneumatic source (not shown) to conduit the silicon liquid discharged from the silicon liquid supply unit 10 and the silicone liquid supply unit 10 for discharging the silicone liquid stored therein to the outside by air pressure. Supplied via (L1) via a nozzle portion (20) with a needle valve type valve therein for injecting silicon liquid onto the substrate, and via a conduit (L2) with an electronically controlled opening and closing valve (V2) interposed therebetween. Supplying compressed air to the nozzle unit 20 and supplying compressed air to the nozzle unit 20 or discharging the compressed air via a conduit L3 having an electronic control opening / closing valve V3 interposed therebetween. The control unit 30 is connected to a pneumatic source (not shown).

The silicone fluid supply unit 10 has a reservoir 1 for storing the silicone fluid, an electronically controlled opening and closing valve V1 interposed therebetween, one end of which is connected to the pneumatic source, and the other end of which is in circulation with the inside of the reservoir 1. Compressed air line (2), one end of which is connected to the inside of the reservoir (1) so as to be connected, but located at a position higher than the water level (S) of the silicon liquid stored in the reservoir (1). The conduit L1 is located in the silicone liquid stored in 1) and the other end thereof is connected to the nozzle unit 20.

In addition, the nozzle unit 20, as shown in Figure 2, a compressed air flow passage 430 for discharging the compressed air adjacent to the outer periphery of the nozzle hole 420 in a state of mounting a known needle valve type valve And a nozzle unit having a first body 200, a second body 300 detachably coupled to the first body, and a nozzle 400 detachably coupled to the first body.

The first body 200 has an inlet 210 connected to the conduit L1 on one side, an inlet 230 connected to the conduit L2 on the other side, and disposed at the center of the inlet 210. The flow of the silicon liquid flow path 220 and the compressed air flow path 240 disposed outside the silicon liquid flow path 220 and distributed to the inlet 230 is formed.

The nozzle 400 is distributed in the center with the silicon fluid flow path 220 and the tip 221 is a silicon flow path 410 in a triangular shape so as to act as a valve seat, the center of the tip in the state flowing with the silicon flow path A compressed air flow path 430 is formed outside the nozzle hole 420, the silicon flow path 410 and the nozzle hole 420 in a state that is not circulated to flow through the compressed air flow path 240. It is.

Here, the compressed air flow path 240 and the compressed air flow path 430 contact each other in order to easily supply compressed air to the compressed air flow path 430 having a substantially conical shape in the compressed air flow path 240 having a straight shape. An annular ring groove 250 is formed at the front end surface of the first body 200.

An upper portion of the first body 200 is formed with the bore 260 disposed on the same axis as the silicon flow path 220 and circulated with the silicon flow path 220. The bore 260 and the In the silicon flow path 220, a pin P having a tip shape corresponding to the tip 221 of the silicon flow path 410 is inserted to be movable upward and downward to protrude toward the second body 300.

A lower portion of the second body 300 is formed with a bore 310 for internally engaging the upper portion of the first body 200 to detachably fasten the first body 200, the pin (P) A bore 330 is formed to receive the spring 320 which is circumscribed in the protruding portion of the cooperator in cooperation with the bore 260. The bores 310 and 330 are disposed on the same axis as the silicon flow path 220.

In addition, a bore 340 disposed on the same axis as the bore 330 and circulating with the bore 330 is formed on an upper portion of the second body 300, and an upper portion of the pin P It protrudes into the bore 340 via the bores 260 and 330.

The upper end of the pin (P) is fixed to the piston 350 is inscribed in the bore 340 to be movable in the bore (340). In the bore 340, the pressing piece 360 having a receiving space 361 formed therein to accommodate the spring 352 whose one end is circumscribed in the protrusion 351 protruding from the center of the piston 350 is movable up and down. It is inscribed. Here, the spring 352 presses the piston 350 downward and presses the pressing piece 360 upward.

In addition, the second body 300 includes a cover 370 that covers the bore 340 and restricts upward movement of the pressing piece 360 and at the same time a screw formed at the center of the cover 370. The silicon liquid amount adjusting piece 380 is provided with a threaded portion 381 that is screwed up and down through the machined through hole 371.

Here, when the silicone liquid amount adjusting piece 380 is turned left and right, the screw portion 381 is moved up and down, and thus the pressing piece 360 is also moved up and down, thereby increasing the upward movement of the piston 350. By limiting the length, the distance between the tip of the pin (P) and the tip 221 of the silicon flow path 410 is limited, and eventually, the amount of silicon liquid flowing into the nozzle hole 420 can be adjusted. .

In addition, the second body 300 is formed with an inlet and outlet 390 flowing through the bore 340, the inlet and outlet 390 is interposed in the middle of the conduit (L3) to control the control unit 30. The compressed air flowed into the bore 340 or flowed into the bore 340 through the conduit L3 through the receiving electronically controlled open / close valve V3. The electronically controlled open / close valve V3. It serves to discharge to the outside via the conduit (L3) through).

Here, the compressed air introduced into the bore 340 via the inlet and outlet 390 moves the piston 350 upwards, and according to the movement, the pin P having one end inscribed in the piston 350 is Moved upwards, the tip 221 of the silicon flow passage 410 is separated from the tip of the fin P, so that the inlet 210, the silicon liquid flow passage 220, the silicon flow passage 410 and the nozzle hole 420 are moved. While causing the ejection of the silicon liquid through, the compressed air discharged from the bore 340 via the inlet and outlet 390 moves the piston 350 downward and one end of the piston 350 in accordance with the movement The inscribed fins P are moved downwards so that the tip 221 of the silicon flow passage 410 is in contact with the tip of the fin P, thereby blocking the nozzle hole 420 so that the silicon liquid may form the nozzle hole 420. Do not blow out to the outside.

The control unit 30 is provided with a compressed air supply connection port 31 connected to the conduit (L2), compressed air supply and discharge connection port (32) connected to the conduit (L3), the connection ports (31, 32) Each is connected to a pneumatic source, not shown.

In addition, the controller 30 includes a timer 33 and an operation switch 34, and as shown in FIG. 3, the following control can be performed.

First, when the movable switch 34 is turned ON, the control unit 30 opens the electronic control valve V1 to open the compressed air from the pneumatic source via the compressed air line 2 to the air supply unit 10. The silicon liquid flow path 220 and the silicon are supplied through the inlet 210 of the nozzle unit 20 by supplying the liquid into the reservoir 1 to pressurize the silicon liquid stored in the reservoir 1 through the conduit L1. The compressed air flow path is supplied through the inlet 230 of the nozzle unit 20 via the conduit L2 by supplying the cone liquid to the oil passage 410 and opening the solenoid control valve V2 to open the compressed air from the pneumatic source. 240 and the compressed air passage 430 is prepared to discharge the silicone liquid out of the nozzle unit 20 through the nozzle hole 420.

Then, the controller 30 repeatedly opens and closes the electronically controlled open / close valve V3 and repeats the compressed air from the pneumatic source through the inlet and outlet 390 of the nozzle unit 20 via the conduit L3. The piston 350 is moved up and down by supplying it into the bore 340 so that the tip of the pin P is spaced / contacted from the tip 221 of the silicon channel 410 so that the silicon channel 410 and the nozzle hole ( 420 is passed / blocked so that the silicon liquid in the silicon flow passage 410 is discharged / not discharged out of the nozzle hole 420. At this time, since the compressed air is continuously discharged from the compressed air flow path 430 disposed outside the nozzle hole 420, the silicon liquid discharged from the nozzle hole 420 by the Bernoulli law is discharged from the compressed air flow path 430. As it moves toward the compressed air, it is discharged in the sprayed state together with the compressed air.

Then, when the movable switch 34 is OFF, the solenoid control valve V1 and the solenoid control valve / ventilation valve V3 are closed, and the solenoid control valve / vent valve V3 is vented to the outside. To stop the supply of the silicone liquid to the nozzle unit 20, and discharge the compressed air introduced into the bore 340 to the outside through the conduit L3 and the electronically controlled opening / closing valve V3. ), The timer 33 is operated while stopping the discharge of the silicon liquid from the nozzle 400 by stopping the tip of the pin P to block the nozzle hole 420.

At this time, the silicone liquid remains in the nozzle hole 420 when the silicone liquid is injected. However, in this embodiment, since the electronic control valve V2 remains open, the compressed air continues to be discharged from the compressed air flow path 430, so that the silicone liquid remaining in the nozzle hole 420 is Bernoulli. By the law (high pressure head is low pressure head) is discharged out of the nozzle hole 420 together with the discharged compressed air, so that the silicone liquid does not remain in the nozzle hole (420).

Then, when the timer 33 indicates a predetermined time, the electromagnetic control valve V2 is closed.

According to the silicon coating device and method according to the present invention, the highly viscous silicone liquid can be injected through the nozzle hole of the nozzle due to the discharge of compressed air through the compressed air flow path discharged outside the nozzle hole, The highly viscous silicone liquid hardens to block the nozzle hole due to the discharge of compressed air through the compressed air flow path.

Claims (8)

On the way, the electronically controlled opening and closing valve (V1) is interposed, one end is connected to the pneumatic source, the other end is supplied with air pressure by the compressed air line (2) connected to the inside of the storage container (1) so as to be circulated to receive the inside Silicone liquid supply unit 10 for discharging the silicone liquid stored in the outside; A silicon flow passage 410 which is supplied / rejected from the silicon liquid supply unit 10 via a conduit L1 and is circulated / blocked by a needle valve type valve built therein to inject silicon liquid onto a substrate; A nozzle unit 20 in which a nozzle hole 420 is formed; And Compressed air is supplied to the compressed air flow path 240 and the compressed air flow path 430 formed to be distributed to each other in the nozzle unit 20 via a conduit L2 having an electronic control valve V2 interposed therebetween. And supply compressed air to the bore 340 which can induce the opening and closing of the needle valve built in the nozzle unit 20 via the conduit L3 in which the electronic control opening / closing valve V3 is interposed. Or a control unit 30 connected to the pneumatic source for discharging the compressed air. Here, the compressed air flow path 430 is disposed adjacent to the outer circumference of the nozzle hole 420, The silicon liquid supply unit 10 is a storage container (1) for storing the silicone liquid, the compressed air line (2) is located at a position higher than the water level (S) of the silicone liquid stored in the storage container (1), One end is connected to the inside of the reservoir (1) for circulation and is located in the silicon liquid stored in the reservoir (1), and the other end is in the silicon liquid flow path 220 and the nozzle hole (420) of the nozzle unit (20) And a conduit (L1) in circulation. delete The method of claim 1, The nozzle unit 20 includes a first body 200, a second body 300 detachably coupled to the first body, and a nozzle 400 detachably coupled to the first body. , The first body 200 has an inlet 210 connected to the conduit L1 on one side, an inlet 230 connected to the conduit L2 on the other side, and disposed at the center of the inlet 210. The flow of the silicon liquid flow path 220, and the compressed air flow path 240 is disposed outside the silicon liquid flow path 220 and circulated with the inlet 230, The nozzle 400 is distributed in the center with the silicon fluid flow path 220 and the tip 221 is a silicon flow path 410 in a triangular shape so as to act as a valve seat, the center of the tip in the state flowing with the silicon flow path A compressed air flow path 430 is formed outside the nozzle hole 420, the silicon flow path 410 and the nozzle hole 420 in a state that is not circulated to flow through the compressed air flow path 240. It is An upper portion of the first body 200 is formed with the bore 260 disposed on the same axis as the silicon flow path 220 and circulated with the silicon flow path 220. The bore 260 and the In the silicon flow path 220, a pin P having a tip corresponding to the tip 221 of the silicon flow path 410 is inserted to be movable up and down to protrude toward the second body 300. A lower portion of the second body 300 is formed with a bore 310 for internally engaging the upper portion of the first body 200 to detachably fasten the first body 200, the pin (P) A bore 330 is formed to accommodate the spring 320 which is circumscribed in the protruding portion of the cooperating with the bore 260, The upper portion of the second body 300 is formed with a bore 340 disposed on the same axis as the bore 330 and flows with the bore 330, the upper portion of the pin (P) is the bore ( Protrude into the bore 340 via 260, 330, The upper end of the pin (P) is fixed to the piston 350 is inscribed in the bore 340 movably in the bore 340, the center portion of the piston 350 in the bore 340 The silicone coating device, characterized in that the pressing piece (360) formed with a receiving space (361) for accommodating the spring 352, one end is circumscribed in the protruding portion (351) protruded to the upper and lower movable. The method of claim 3, wherein The compressed air flow path 240 and the compressed air flow path 430 contact the compressed air flow path 240 to easily supply compressed air to the compressed air flow path 430 having a substantially conical shape in the compressed air flow path 240. An annular ring groove 250 is formed at the front end surface of the first body 200, The bores 310 and 330 are disposed on the same axis as the silicon flow path 220. The spring (352) is pressing the piston (350) downward and the pressing device (360) is characterized in that the silicone coating device. The method according to claim 3 or 4, The second body 300 includes a cover 370 that covers the bore 340 and restricts upward movement of the pressing piece 360, and at the same time, a screw is formed in the center of the cover 370. And a silicon liquid amount adjusting piece (380) having a threaded portion (381) which is moved up and down in a threaded manner through a through hole (371). The method according to claim 3 or 4, The second body 300 is formed with an inlet and outlet 390 flowing through the bore 340, the inlet and outlet 390 is interposed in the middle of the conduit (L3) is controlled by the control unit 30 Compressed air is supplied to the bore 340 through the conduit L3 through the control opening / closing valve V3 or the compressed air introduced to the bore 340 is opened. Silicone coating device, characterized in that the discharge through the conduit (L3) through the outside. The method according to claim 1 or 3, The control unit 30 is provided with a compressed air supply connection port 31 connected to the conduit (L2), compressed air supply and discharge connection port (32) connected to the conduit (L3), the connection ports (31, 32) Each is connected to a pneumatic source, The control unit 30 is provided with a timer 33 and the movable switch 34, characterized in that the silicon coating device. When the movable switch 34 is turned on, the solenoid control valve V1 is opened to supply the compressed air from the pneumatic source into the reservoir 1 of the silicon liquid supply part 10 via the compressed air line 2, thereby storing the reservoir. (1) pressurizing the silicon liquid stored in the silicon liquid via the conduit (L1) through the inlet 210 of the nozzle portion 20 to supply the silicon liquid to the silicon liquid flow path 220 and the silicon flow path 410 At the same time, the solenoid control valve V2 is opened and the compressed air flow path 240 and the compressed air flow path 430 through the inlet 230 of the nozzle unit 20 via the conduit L2 through the compressed air from the pneumatic source. Preparing to discharge the silicon liquid out of the nozzle unit 20 through the nozzle hole 420; Opening and closing the electronically controlled opening / closing valve V3 is repeated to supply compressed air from the pneumatic source into the bore 340 through the inlet and outlet 390 of the nozzle unit 20 via the conduit L3. The piston 350 moves upward and downward to allow the tip of the pin P to be spaced / contacted from the tip 221 of the silicon channel 410 so that the silicon channel 410 and the nozzle hole 420 flow / block. Discharging / non-discharging the silicon liquid in the silicon flow passage 410 out of the nozzle hole 420; When the movable switch 34 is turned off, the solenoid control valve V1 and the solenoid control opening / closing valve V3 are closed, and the solenoid control opening / closing valve V3 is kept in a ventilated state with the outside, and the nozzle unit 20 is closed. Stop supply of the silicone liquid to the), and discharge the compressed air introduced into the bore 340 to the outside through the conduit (L3) and the electronically controlled open / close valve (V3), the piston 350 is moved downward to pin Starting the timer 33 while stopping the discharge of the silicon liquid from the nozzle 400 by causing the tip of P to block the nozzle hole 420; And And when the timer (33) indicates a predetermined time, closing the electronic control valve (V2).

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