KR101901970B1 - UV curing apparatus - Google Patents

Abstract

According to an embodiment of the present invention, provided is a UV curing apparatus. The UV curing apparatus according to one embodiment of the present invention includes: a chamber unit including a storage space for mounting an object therein, a transparent window on one surface, and a cover unit for sealing the storage space; a gas inlet unit for inserting inert gas into the chamber unit; a driving unit slide- moving the chamber unit; and a UV module installed on the moving path of the chamber unit, and emitting UV rays through the transparent window to the object. The curing quality of a coating liquid applied to the surface of an object and cured by UV light can be improved by the UV curing apparatus of the present invention.

Description

[0001] The present invention relates to a UV curing apparatus,

The present invention relates to an ultraviolet curing apparatus, and more particularly, to an ultraviolet curing apparatus having a structure capable of improving the curing quality of a coating liquid applied to a surface of an object and cured by ultraviolet rays.

In general, coating means to form a film on the surface of an object for the purpose of preventing damage to the surface of the object and adherence of the object and adjusting the reflectance. There are many types of coating methods, but ultraviolet curing coatings have been widely used in recent years.

UV curing coating is a coating method in which UV coating liquid is applied to the surface of the object and UV coating is applied to cure the UV coating liquid to form a coating film. The coating properties of the coating film are advantageous such as high gloss, high hardness and chemical resistance Respectively. In addition, the curing speed of the UV coating solution is faster than that of the thermosetting method, so that the productivity is improved, and the heat treatment process is omitted and the production process can be also reduced. In addition, since no organic solvent is used, the effect on the environment can be minimized and it is easy to apply to an object easily deformed by heat because of using ultraviolet rays. In particular, the ultraviolet curing coating has a very short curing speed, ranging from several seconds to several tens of seconds, and is very advantageous for continuously coating an optical film used in the display field.

However, ultraviolet rays having a wavelength of 200 nm or less absorb oxygen in the air to generate ozone, and oxygen in the air has a problem of inhibiting the chemical reaction by the ultraviolet light of the UV coating solution and lowering the curing density. Particularly, when the UV coating liquid is contacted with oxygen when the optical film is coated, the optical function is degraded due to oxidation due to the oxidation reaction.

In order to reduce the concentration of oxygen in contact with ultraviolet rays by injecting an inert gas, in particular, nitrogen gas, nitrogen gas is injected onto the moving path of the object so that the injected nitrogen gas is easily dispersed, As a result, there is a problem that the UV coating liquid inevitably comes into contact with oxygen.

Korean Registered Patent No. 10-1032398 Nov. 25, 2011

An object of the present invention is to provide an ultraviolet curing apparatus having a structure capable of improving the curing quality of a coating liquid which is coated on the surface of an object and is cured by ultraviolet rays.

The technical objects of the present invention are not limited to the technical matters mentioned above, and other technical subjects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an ultraviolet curing apparatus comprising: a chamber unit having a receiving space in which an object is placed, a transparent window formed on a surface thereof, and a cover for sealing the receiving space; A gas injection unit for injecting an inert gas into the chamber unit, a driving unit for slidably moving the chamber unit, and an ultraviolet ray irradiation unit for irradiating ultraviolet rays to the object through the transparent window, Module.

The lid part is hinged to the chamber unit and can be opened and closed in a hinged manner.

The lid part may be formed on the upper end of the chamber unit, and the transparent window may be formed on the lid part.

The ultraviolet curing apparatus may further include a seating plate connected to the lid unit and extending to the inside of the accommodation space to seat the object, wherein the lid unit is formed on a side of the chamber unit, .

The chamber unit may further include a cylinder unit connected between the body portion having the accommodating space formed therein and the lid portion for sealing the body portion and having a length expanded and contracted to open and close the lid portion.

The ultraviolet curing apparatus may further include a nozzle unit installed inside the chamber unit and spraying the coating liquid onto the object.

The ultraviolet curing apparatus may further include a roller unit installed inside the chamber unit and moving the accommodating space in a horizontal direction to push and apply the coating liquid sprayed on the surface of the object.

The pressure of the inert gas inside the accommodation space can be maintained at a pressure higher than atmospheric pressure.

The ultraviolet curing apparatus may further include a vacuum adsorption unit for vacuum-adsorbing the object under the chamber unit.

According to the present invention, nitrogen gas is injected into the chamber unit of the closed structure to prevent the coating liquid from contacting with oxygen as much as possible. Therefore, the generation of ozone can be minimized during the process, and the chemical reaction by the ultraviolet light of the coating solution can be smoothly performed, thereby improving the curing quality. Further, since the nitrogen gas is discharged through the exhaust part when the process is completed, an accident caused by the nitrogen gas can be prevented in advance.

1 is a perspective view illustrating an ultraviolet curing apparatus according to an embodiment of the present invention.
Fig. 2 is a cross-sectional view of the ultraviolet curing device of Fig. 1 cut longitudinally. Fig.
3 is an enlarged perspective view of the chamber unit.
4 is a side view of the chamber unit.
5 is a cross-sectional view showing the chamber unit cut in the lateral direction.
6 is a flowchart for explaining an operation process of the ultraviolet curing apparatus.
7 is a view showing an operation process of the ultraviolet curing apparatus.
8 is an enlarged perspective view of a chamber unit according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, a UV curing apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 7. FIG.

An ultraviolet curing apparatus according to an embodiment of the present invention is an apparatus for forming a coating film by curing a UV coating liquid by irradiating ultraviolet rays onto a UV coating liquid applied to a surface of an object. For example, As shown in FIG.

The ultraviolet curing apparatus injects nitrogen gas into the chamber unit of the closed structure to block the contact of the coating liquid with oxygen as much as possible. Therefore, the generation of ozone can be minimized during the process, and the chemical reaction by the ultraviolet light of the coating solution can be smoothly performed, thereby improving the curing quality. Further, since the nitrogen gas is exhausted through the exhaust part when the process is completed, an accident caused by the nitrogen gas can be prevented in advance.

Hereinafter, the ultraviolet curing apparatus 1 will be described in detail with reference to Figs. 1 to 5. Fig.

FIG. 1 is a perspective view illustrating an ultraviolet curing apparatus according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view of the ultraviolet curing apparatus of FIG. Fig. 3 is a perspective view showing an enlarged view of the chamber unit, Fig. 4 is a side view of the chamber unit, and Fig. 5 is a cross-sectional view showing the chamber unit cut in the transverse direction.

The ultraviolet curing apparatus 1 according to the present invention includes a chamber unit 10, a gas injection unit 20, a driving unit 30, and an ultraviolet module 40.

The chamber unit 10 is a tubular member, and a receiving space 10a in which the object 100 is seated is formed therein. Here, the object 100 means an object to be cured by irradiation with ultraviolet rays, and may be, for example, an optical film used in a display field. The object 100 may be in a state in which the surface is irradiated with ultraviolet light so that the coating liquid to be cured is applied or not applied. Hereinafter, the surface of the object 100 is limited to a state in which the coating liquid is not applied, and will be described in detail.

A transparent window 11 is formed on one side of the chamber unit 10. The transparent window 11 may be formed of any one of quartz, pyrex, crystal, and glass, which is an optical filter through which only ultraviolet rays of a desired wavelength can be transmitted. That is, ultraviolet rays emitted from the ultraviolet ray module 40, which will be described later, are transmitted through the transparent window 11 and irradiated onto the surface of the object 100. The chamber unit 10 is formed with a lid 12 on one side.

The lid portion 12 can be hinged or slidably coupled to the chamber unit 10 in a rotatable manner by sealing the accommodation space 10a. The cover unit 12 is formed in the chamber unit 10 so that one side of the accommodation space 10a can be opened and closed so that the object 100 can be easily taken in and out of the accommodation space 10a. A sealing member (not shown) is provided between the lid unit 12 and the chamber unit 10 so that airtightness can be maintained when the accommodation space 10a is sealed. Hereinafter, the structure in which the lid part 12 is hinged to the chamber unit 10 will be described more specifically.

3 and 4, the lid unit 12 is hinged to the chamber unit 10 and can be opened and closed in a hinged manner. The cover unit 12 is hinged to the chamber unit 10 and opened and closed in a hinged manner so that the object 100 can be taken in or out even if the cover 12 is partly turned and opened. Also, the thick object 100 can be easily inserted and removed

 The lid part 12 is formed at the upper end of the chamber unit 10 so that one side can be hinged to the chamber unit 10 and the transparent window 11 can be formed in the lid part 12. [ The lid part 12 is formed on the upper end of the chamber unit 10 and the transparent window 11 is formed on the lid part 12 so that ultraviolet rays emitted from the ultraviolet module 40 pass through the transparent window 11 And can be irradiated onto the surface of the object 100. [ However, the lid portion 12 is not limited to being formed at the upper end of the chamber unit 10. For example, the lid portion 12 may be formed at the lower end or the side surface of the chamber unit 10. [ The transparent window 11 may be formed at the upper end of the chamber unit 10 when the lid part 12 is formed at the lower end or the side surface of the chamber unit 10. [

The chamber unit 10 includes a main body portion 13 formed with a receiving space 10a and a lid portion 12 hinged to the main body portion 13 to seal the main body portion 13, And the lid portion 12 can be opened and closed by the cylinder unit 14. [ The cylinder unit 14 is connected between the main body portion 13 and the lid portion 12 and can be expanded and contracted to open and close the lid portion 12. For example, when the length of the cylinder unit 14 is extended, the lid unit 12 rotates around the hinge axis to open the accommodation space 10a, and when the length of the cylinder unit 14 is shortened, The part 12 can be rotated around the hinge axis to seal the accommodation space 10a. The cylinder unit 14 is formed in the form of a pneumatic cylinder, and includes a cylinder 14a and a piston 14b.

The cylinder 14a is a tubular member whose one side is opened and can be pivotally coupled to the main body portion 13. [ The cylinder 14a receives the piston 14b therein. The piston 14b is a bar or rod member, one side of which is rotatably engaged with the lid portion 12, and the other side of which is driven inside the cylinder 14a. Therefore, when air is injected into the cylinder 14a, the piston 14b may move and a part of the piston 14b may protrude outwardly of the cylinder 14a, thereby extending the length of the cylinder unit 14, Can be opened. On the contrary, when the air in the cylinder 14a is discharged, the piston 14b can be moved and a part of the cylinder 14a can be received inside the cylinder 14a. As a result, the length of the cylinder unit 14 is shortened, ). Although the cylinder unit 14 is shown on both sides of the chamber unit 10 in the figure, the number and position of the cylinder unit 14 may be added or changed as necessary. Further, the lid portion 12 is not limited to being opened and closed by the cylinder unit 14, and may be modified into various structures capable of opening and closing the lid portion 12. For example, the lid portion 12 may be opened or closed by a gear structure or a belt structure.

The chamber unit 10 is connected to the gas injection unit 20. The gas injection unit 20 injects an inert gas into the chamber unit 10, and can inject inert gas through one side of the chamber unit 10. Specifically, the gas injection unit 20 is formed of a flexible tube that can be bent flexibly, and has one end communicating with the inside of the chamber unit 10 through the chamber unit 10 and the other end connected to the gas storage tank The inert gas can be injected. Curing of the coating liquid can be performed in a nitrogen atmosphere by injecting an inert gas, particularly nitrogen gas, into the chamber unit 10 of the closed structure by the gas injection unit 20. [ In other words, the coating liquid can be cured in a state in which the contact with oxygen is blocked, so that the chemical reaction by the ultraviolet light of the coating liquid is smooth and the curing quality can be improved. In particular, when the object 100 is an optical film, oxidation of the coating liquid by the oxidation reaction is prevented, optical function can be improved, oxygen absorption into ultraviolet rays can be prevented, and generation of ozone can be minimized.

The chamber unit 10 is provided with a sensor unit 84 for measuring the concentration of an inert gas, in particular nitrogen gas, and the gas injection unit 20 is connected to the sensor unit 84 to control the injection of the inert gas can do.

In addition, the pressure of the inert gas inside the accommodation space 10a can be maintained at a pressure higher than the atmospheric pressure. That is, the gas injection unit 20 injects the inert gas so that the pressure of the inert gas inside the accommodation space 10a is maintained higher than the atmospheric pressure. The pressure of the inert gas inside the accommodation space 10a is maintained at a pressure higher than the atmospheric pressure so that the inflow of air into the inside of the accommodation space 10a can be blocked. Therefore, the contact between the coating liquid and oxygen can be blocked as much as possible, and the concentration of the inert gas can be kept uniform, so that the curing quality can be further improved.

The chamber unit 10 may be connected to the first air injection unit 80, the second air injection unit 81, and the exhaust unit 82.

The first air injection unit 80 injects high-temperature air into the chamber unit 10, and can inject high-temperature air through one side of the chamber unit 10. Specifically, the first air injection unit 80 is formed as a flexible tube that can be flexibly bent, and has one end communicating with the inside of the chamber unit 10 through the chamber unit 10, and the other end being connected to the air storage tank Not shown) to inject high temperature air. The first air injection unit 80 may be set to inject the high temperature air before the gas injection unit 20 injects the inert gas into the chamber unit 10 after the coating liquid is injected. The high temperature air is injected into the chamber unit 10 of the closed structure by the first air injection unit 80 so that the organic solvent contained in the coating liquid evaporates and the coating liquid can be dried, The temperature of the inside of the coating liquid can be increased and the coating liquid can be easily cured.

The second air injection unit 81 injects room-temperature air into the chamber unit 10, and can inject room-temperature air through one side of the chamber unit 10. Specifically, the second air injection unit 81 is formed as a flexible tube that can be flexibly bent, and has one end communicating with the interior of the chamber unit 10 through the chamber unit 10, and the other end being connected to the air storage tank Not shown) to inject air at room temperature. At this time, the first air injection unit 80 and the second air injection unit 81 may receive air from the same air storage tank or air from different air storage tanks. By injecting the air at room temperature into the chamber unit 10, the second air injection unit 81 can easily cool the coating liquid after curing. That is, the second air injection unit 81 is set to inject room-temperature air into the chamber unit 10 after curing of the coating liquid is completed.

The exhaust unit 82 sucks inert gas or air in the chamber unit 10 and discharges the inert gas or air to the outside. The inert gas or air can be sucked through one side of the chamber unit 10. Specifically, the evacuation section 82 is formed of a flexible tube that can be bent flexibly. One end of the evacuation section 82 communicates with the inside of the chamber unit 10 through the chamber unit 10, and the other end thereof is connected to a suction pump (not shown) So that an inert gas or air can be sucked. Since the exhaust unit 82 sucks the inert gas or air in the chamber unit 10, the nitrogen gas can be easily discharged after the completion of the process, thereby preventing an accident caused by the nitrogen gas.

On the other hand, the chamber unit 10 can be slid by the driving unit 30. The driving unit 30 reciprocally slides the chamber unit 10 in a horizontal direction, and one side of the chamber unit 10 can be connected to the chamber unit 10. 2, the driving unit 30 includes a driving motor 31, a first pulley 32, a second pulley 33, and a belt unit 34. [

The driving motor 31 generates a driving force necessary for moving the chamber unit 10 and can be seated on the main body 1a of the ultraviolet curing apparatus 1. [ A first pulley 32 is connected to one side of the drive motor 31. The first pulley 32 is a shaft-wheel-shaped member and can be rotatably coupled to the drive motor 31. The first pulley 32 hangs on one side of a belt portion 34 to be described later and is arranged on the same plane as the second pulley 33. [ The second pulley 33 is formed of a shaft-wheel-like member like the first pulley 32 and is rotatably coupled to the main body 1a of the ultraviolet curing apparatus 1. [ That is, the first pulley 32 and the second pulley 33 hang on one side and the other side of the belt portion 34, respectively, and the belt portion 34 is engaged with the first pulley 32 and the second pulley 33 33 to form a closed loop and circulate. The belt unit 34 has the chamber unit 10 fixed to one side. When the first pulley 32 is rotated by receiving the driving force of the driving motor 31, the belt unit 34 moves in the rotating direction of the first pulley 32 and moves the chamber unit 10 in the horizontal direction . For example, when the first pulley 32 rotates counterclockwise, the chamber unit 10 can move from right to left, and when the first pulley 32 rotates clockwise, the chamber unit 10 10 can move from left to right. However, the drive unit 30 is limited to the drive motor 31, the first pulley 32 and the second pulley 33, and the belt unit 34 to slide the chamber unit 10 And can be modified into various structures capable of sliding movement of the chamber unit 10. For example, the driving unit 30 may be formed in a gear structure to slide the chamber unit 10.

A separate rail (not shown) for guiding the movement of the belt portion 34 may be formed on the main body 1a of the ultraviolet curing apparatus 1, and at least one side of the rail may be provided with a guide A tray guide 36 may be formed. As described above, the gas injecting section 20, the first air injecting section 80, the second air injecting section 81, and the exhausting section 82 are formed in the form of a flexible flexible tube, When the unit 10 is slidingly moved, it can be pulled forward or pushed back and tangled with each other to block the movement path of the chamber unit 10. [ Therefore, at least a part of the gas injecting section 20, the first air injecting section 80, the second air injecting section 81 and the exhausting section 82 is accommodated in the cable tray 35, It is possible to prevent the movement path of the movable member 10 from being blocked in advance. The cable tray 35 is formed by connecting a plurality of links in series to each other, and one side of the cable tray 35 may be connected to the chamber unit 10 to move integrally with the chamber unit 10.

On the movement path of the chamber unit 10, an ultraviolet module 40 is installed. The ultraviolet module 40 may be disposed at an upper portion of the chamber unit 10 by irradiating the object 100 with ultraviolet rays through the transparent window 11. [ For example, the ultraviolet module 40 may be disposed between the first pulley 32 and the second pulley 33, and may be spaced apart from the upper surface of the chamber unit 10 by a predetermined height. Although not shown in detail, the ultraviolet module 40 is formed of a lamp 40a that emits ultraviolet rays and a housing 40b that houses a lamp. Ultraviolet rays emitted from the lamp 40a pass through the transparent window 11 And can be irradiated onto the surface of the object 100. Since the ultraviolet module 40 is generally provided in the ultraviolet curing apparatus, a detailed description thereof will be omitted.

The nozzle unit 50 may be installed inside the chamber unit 10. The nozzle unit 50 may inject the coating liquid to the object 100 and may be slidably coupled within the chamber unit 10 as needed. By joining the nozzle portion 50 in a slidable manner, the spraying of the coating liquid can be uniformly sprayed over the entire area, thereby improving the curing quality. The nozzle unit 50 can be slid along the rail 51 and supplied with the coating liquid from the coating liquid injecting unit 83.

The coating liquid injecting unit 83 can supply the coating liquid to the nozzle unit 50 through the one side of the chamber unit 10 by supplying the coating liquid into the nozzle unit 50. Specifically, the coating liquid injecting section 83 is formed of a flexible tube that can be flexibly refracted so that one side communicates with the nozzle section 50 directly or indirectly through the chamber unit 10, And may be connected to a tank (not shown) to supply the coating liquid. When the coating liquid injecting unit 83 is indirectly connected to the nozzle unit 50, a separate tube that can be stretched in the longitudinal direction may be connected between the coating liquid injecting unit 83 and the nozzle unit 50. The coating liquid injecting portion 83 may be at least partially accommodated in the cable tray 35, like the gas injecting portion 20. However, the present invention is not limited to spraying the coating liquid through the nozzle unit 50, and the coating liquid may be directly sprayed from the coating liquid injecting unit 83 as needed.

The coating liquid sprayed from the nozzle unit 50 can be applied to the object 100 by the roller unit 60. The roller unit 60 can be installed inside the chamber unit 10 by horizontally moving the accommodation space 10a and pushing the coating liquid sprayed on the surface of the object 100 to be applied. Specifically, the roller unit 60 moves along a separate rail 61 in a direction perpendicular to the moving direction of the nozzle unit 50, and can be formed rotatable as necessary. The roller unit 60 moves the accommodating space 10a in the horizontal direction, in particular, in the direction perpendicular to the moving direction of the nozzle unit 50, so that the coating liquid is ejected from the nozzle unit 50, It can be applied to the surface of the object 100 in a uniform thickness over the entire area without aggregation, thereby further improving the curing quality. However, the coating liquid is not limited to be applied to the surface of the object 100 by the roller unit 60, and the coating liquid may be applied directly in the coating liquid injection unit 83 as needed.

A vacuum adsorption unit 70 may be formed on one side of the chamber unit 10. The vacuum adsorption unit 70 may be installed outside or inside the chamber unit 10 by vacuum adsorbing the object 100 under the chamber unit 10. For example, as shown in FIG. 4, the vacuum adsorption unit 70 can be installed outside the chamber unit 10, and when the vacuum adsorption unit 70 is installed outside the chamber unit 10 And a plurality of through holes 10b passing through the chamber unit 10 may be formed on the overlapping surface of the chamber unit 10 and the vacuum adsorption unit 70. [ That is, the vacuum adsorption unit 70 can adsorb the object 100 to the chamber unit 10 by sucking air through the plurality of through holes 10b. The vacuum adsorption unit 70 vacuum-adsorbs the object 100 to the chamber unit 10 so that it does not move at the position where the object 100 is seated and overlaps with the transparent window 11 even if the chamber unit 10 slides As shown in Fig. Particularly, when the object 100 is a thin optical film, the inert gas or air injected from the gas injecting unit 20, the first air injecting unit 80, or the second air injecting unit 81, 100 can be prevented from deviating from the optimum ultraviolet irradiation position and movement of the object 100 by the inert gas or air sucked into the exhaust part 82 after the coating liquid is cured can be prevented.

Hereinafter, with reference to Figs. 6 and 7, the operation of the ultraviolet curing apparatus 1 will be described in more detail.

FIG. 6 is a flow chart for explaining the operation of the ultraviolet curing apparatus, and FIG. 7 is a view showing an operation process of the ultraviolet curing apparatus.

The ultraviolet curing apparatus 1 according to the embodiment of the present invention can inject nitrogen gas into the chamber unit 10 having a closed structure to block the contact of the coating liquid with oxygen as much as possible. Therefore, the generation of ozone can be minimized during the process, and the chemical reaction by the ultraviolet light of the coating solution can be smoothly performed, thereby improving the curing quality. In addition, since the nitrogen gas is discharged through the exhaust part 82 when the process is completed, an accident caused by the nitrogen gas can be prevented in advance.

First, referring to FIG. 6 and FIG. 7A, the concentration and injection time of the nitrogen gas to be injected through the control unit (see 90 in FIG. 1), the illuminance of the ultraviolet ray to be irradiated, . The control unit 90 includes a gas injection unit 20, a first air injection unit 80, a second air injection unit 81, an exhaust unit 82, a driving unit 30, an ultraviolet module 40, 50 and the roller unit 60 so as to control the operation of each constitution and may be formed on the one side of the main body 1a of the ultraviolet curing apparatus 1 in the form of a touch screen. When the concentration of the nitrogen gas to be injected through the control unit 90, the injection time, and the illuminance and the light amount of the ultraviolet ray to be irradiated are set, the lid unit 12 rotates as shown in FIG. 7 (a) 10, that is, the accommodation space 10a is opened. The lid unit 12 rotates about the hinge axis as the length of the cylinder unit 14 is extended to open the accommodation space 10a and the object 100 is seated in the accommodation space 10a through the opened one side . At this time, the object 100 is seated in the accommodation space 10a so as to overlap with the transparent window 11, vacuum-adsorbed by the vacuum adsorption unit 70, and held in the state of being fixed to the chamber unit 10 .

At least a part of the gas injecting unit 20, the first air injecting unit 80, the second air injecting unit 81 and the exhausting unit 82 are accommodated in the cable tray 35, (35) can be received inside the tray guide (36).

6 and 7B, when the object 100 is placed in the receiving space 10a, the lid unit 12 is rotated and the chamber unit 10, that is, the receiving space 10a. The cover unit 12 is rotated about the hinge axis to seal the accommodation space 10a as the length of the cylinder unit 14 is shortened and when the accommodation space 10a is closed, ) Is sprayed onto the surface of the coating liquid. At this time, the nozzle unit 50 slides inside the chamber unit 10 and can uniformly spray the coating liquid over the entire area of the object 100. When the nozzle unit 50 ejects the coating liquid, the roller unit 60 moves in the horizontal direction and pushes the sprayed coating liquid to be applied. When the coating liquid is applied to the surface of the object 100, the first air injection unit 80 injects hot air into the chamber unit 10. When the high-temperature air is injected, the organic solvent contained in the coating liquid evaporates, and the temperature inside the chamber unit 10 can be increased while being dried. When the first air injecting unit 80 injects hot air to dry the coating liquid, the gas injecting unit 20 injects inert gas, particularly nitrogen gas, into the chamber unit 10. The gas injection unit 20 injects an inert gas so that the pressure of the inert gas inside the accommodation space 10a is maintained at a pressure higher than atmospheric pressure and the object 100 is placed in the nitrogen atmosphere by the gas injection unit 20 .

Next, referring to FIGS. 6 and 7C, when the injection of the high-temperature air and the inert gas is completed, the chamber unit 10 slides. The driving unit 30 slides the chamber unit 10 to pass the ultraviolet module 40 and the coating liquid applied to the surface of the object 100 can be cured as the chamber unit 10 moves. That is, ultraviolet rays emitted from the ultraviolet module 40 are irradiated to the surface of the object 100 through the transparent window 11 to cure the coating liquid. At this time, the operation of the driving unit 30 may be controlled through the control unit 90 so that the chamber unit 10 may adjust the moving speed.

The gas injection unit 20, the first air injection unit 80, the second air injection unit 81, and the exhaust unit 82 are partially deflected as the chamber unit 10 slides, The cable tray 35 accommodating the gas injection unit 20, the first air injection unit 80, the second air injection unit 81 and the exhaust unit 82 may be partially deflected.

6 and 7 (d), when the chamber unit 10 slides from one side of the main body 1a to the other side and passes through the ultraviolet module 40, The coating liquid applied to the surface is cured.

When the chamber unit 10 slides and reaches the other side from the main body 1a, the gas injection unit 20, the first air injection unit 80, the second air injection unit 81, And the exhaust part 82 are refracted to the maximum and the cable tray 20 which receives the gas injection part 20, the first air injection part 80, the second air injection part 81 and the exhaust part 82 35) is also refracted as much as possible.

6 and 7 (e), when the coating liquid is cured, the driving unit 30 slides the chamber unit 10 back to its original position. During or after the return of the chamber unit 10, the second air injection unit 81 injects room-temperature air into the chamber unit 10 to cool the cured coating liquid. When the chamber unit 10 is returned, the vacuum adsorption of the vacuum adsorption unit 70 is stopped and the lid unit 12 is pivoted to open the accommodation space 10a and the object 100 is opened And can be drawn out from the accommodation space 10a.

Hereinafter, referring to Fig. 8, the chamber unit 10 according to another embodiment of the present invention will be described in detail.

8 is an enlarged perspective view of a chamber unit according to another embodiment of the present invention.

The chamber unit 10 according to another embodiment of the present invention is such that the lid portion 12 is slidably engaged with the chamber unit 10 to seal the accommodation space 10a. The chamber unit 10 according to another embodiment of the present invention is substantially identical to the aforementioned embodiment except that the lid portion 12 is slidably engaged with the chamber unit 10 to seal the accommodation space 10a. . Therefore, the description will be focused on, but unless otherwise noted, the description of the remaining components is replaced by the foregoing.

The chamber unit 10 includes a main body portion 13 formed with a receiving space 10a, a lid portion 12 slidably movably coupled to the main body portion 13 to seal the accommodating space 10a, And a seating plate (15) connected to the plate (12).

The main body 13 has a receiving space 10a formed therein and a transparent window 11 formed at an upper end thereof. The main body part 13 is formed with a side open structure and the lid part 12 is formed on the side surface of the main body part 13 and is slidably coupled to the main body part 13 by the seating plate 15 . The seating plate 15 is connected to one surface of the lid unit 12 which is formed as a plate-like member and contacts the main body unit 13 and extends inside the accommodation space 10a so that the object 100 can be seated on the upper surface have. That is, the lid portion 12 is formed on the side surface of the chamber unit 10, that is, the main body portion 13, and can be opened and closed by sliding in the horizontal direction together with the seating plate 15. [

The lid portion 12 and the seating plate 15 can be opened or closed by the cylinder unit 14. The cylinder unit 14 is connected between the main body portion 13 and the lid portion 12 and can be expanded and contracted to open and close the lid portion 12. For example, the cylinder unit 14 is formed in the form of a pneumatic cylinder, and includes a cylinder 14a and a piston 14b. The cylinder 14a is a tubular member whose one side is opened and can be fixedly coupled to the side surface of the main body portion 13. [ The cylinder 14a receives the piston 14b therein. The piston 14b is a rod or rod member, one side of which is fixedly coupled to the lid 12, and the other side is driven inside the cylinder 14a. Accordingly, when air is injected into the cylinder 14a, the piston 14b may move and a part of the piston 14b may protrude to the outside of the cylinder 14a, thereby extending the length of the cylinder unit 14, Can be opened. On the contrary, when the air inside the cylinder 14a is discharged, the piston 14b can be moved and a part of the cylinder 14a can be received inside the cylinder 14a, thereby shortening the length of the cylinder unit 14, Can be sealed.

Although the cylinder unit 14 is shown on both sides of the chamber unit 10 in the figure, the number and position of the cylinder unit 14 may be added or changed as necessary. Further, the lid portion 12 is not limited to being opened and closed by the cylinder unit 14, and may be modified into various structures capable of opening and closing the lid portion 12. For example, a rack gear may be coupled to one of the body portion 13 and the cover portion 12, and a pinion gear may be coupled to the other of the body portion 13 and the cover portion 12 to open / close the lid portion 12 have.

When the cover 12 is slidably coupled to the chamber unit 10, the vacuum adsorption unit 70 may be installed in the lower part of the seating plate 15 and be located inside the chamber unit 10. That is, a plurality of through holes 10b penetrating through the seating plate 15 are formed on the overlapping surface of the seating plate 15 and the vacuum suction portion 70, and the vacuum suction portion 70 includes a plurality of through holes 10b The object 100 can be sucked to the seating plate 15. In this case, Further, the nozzle unit 50 and the roller unit 60 can be installed on the upper surface of the seating plate 15.

Since the lid portion 12 is slidably coupled to the chamber unit 10, the object 100 can be taken in and out even if the lid portion 12 is partially opened and closed. When the object 100 Can be prevented from being damaged due to contact with the lid part 12.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

1: ultraviolet curing device 1a:
10: chamber unit 10a: accommodation space
10b: through hole 11: transparent window
12: lid part 13: body part
14: cylinder unit 14a: cylinder
14b: piston 15: seat plate
20: gas injection unit 30:
31: drive motor 32: first pulley
33: second pulley 34: belt portion
35: Cable tray 36: Tray guide
40: ultraviolet module 40a: lamp
40b: housing 50: nozzle part
60: Roller unit 70: Vacuum adsorption part
80: first air injection unit 81: second air injection unit
82: exhaust part 83: coating liquid injection part
84: sensor unit 90: control unit
100: object

Claims (9)

A chamber unit having a receiving space in which an object is seated, a transparent window formed on one surface thereof, and a lid part for sealing the receiving space;
A gas injection unit for injecting an inert gas into the chamber unit;
A driving unit for slidingly moving the chamber unit;
An ultraviolet module installed on a moving path of the chamber unit and irradiating the object with ultraviolet rays through the transparent window;
A first air injection unit injecting high-temperature air into the chamber unit before the inert gas is injected; And
And a second air injection unit for injecting room-temperature air into the chamber unit after the inert gas is injected. The method according to claim 1,
Wherein the lid part is hinged to the chamber unit and opened / closed in a hinged manner. 3. The method of claim 2,
Wherein the lid part is formed on the upper end of the chamber unit, and the transparent window is formed on the lid part. The method according to claim 1,
And a seating plate connected to the lid unit and extending to the inside of the accommodation space to seat the object,
Wherein the lid part is formed on a side surface of the chamber unit and slides horizontally together with the seating plate to open and close. The apparatus of claim 1, wherein the chamber unit comprises:
Further comprising a cylinder unit connected between the body portion formed with the accommodating space and the lid portion closing the body portion and having a length expanded and contracted to open and close the lid portion. The method according to claim 1,
And a nozzle unit installed in the chamber unit to jet the coating liquid onto the object. The method according to claim 6,
Further comprising a roller unit installed in the chamber unit and moving the accommodating space in a horizontal direction to push and apply the coating liquid sprayed on the surface of the object. The method according to claim 1,
Wherein a pressure of the inert gas inside the accommodation space is maintained at a pressure higher than atmospheric pressure. The method according to claim 1,
And a vacuum adsorption unit for vacuum-adsorbing the object under the chamber unit.

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