KR102193213B1 - Ultraviolet light curing device to improve the curing performance of 3D laminate - Google Patents

Abstract

The present invention relates to an ultraviolet light curing device for improving the curing performance of a three-dimensional laminate, and a housing that is empty inside and can be opened and closed through a door on the front side, and a three-dimensional laminated body formed under the inner side of the housing. It characterized in that it comprises a cradle formed so that the sieve can be mounted, and a curing unit formed on the inner surface of the housing and curing by irradiating ultraviolet rays on the outer surface of the three-dimensional laminate.

Description

Ultraviolet light curing device to improve the curing performance of 3D laminate

The present invention relates to an ultraviolet light curing apparatus for improving the curing performance of a three-dimensional laminate. When curing a three-dimensional laminate output by a 3D printer, the three-dimensional laminate cured using ultraviolet rays of different wavelengths It relates to an ultraviolet light curing device for improving the curing performance of a three-dimensional laminate to improve strength and shrinkage.

3D printing technology, which is in the spotlight as a next-generation precision processing technology, refers to a technology that produces a three-dimensional object by spraying the material in the X-axis, Y-axis, and Z-axis directions while the material is melted.

In general, 3D printing technology continuously reconstructs a two-dimensional cross section and prints the molten material layer by layer to create a three-dimensional laminate.Since the three-dimensional laminate is made of molten material, it is hardened to fix the shape. A curing process to ensure that it is absolutely necessary.

In general, a method using heat (Fused Deposition Modeling: FDM), laser (Selective lasersintering: SLS), and UV light (Stereolithography Apparatus: SLA, Digital Light Processing: DLP) is commonly used as a means for curing.

However, the material curing method using heat requires a support for the material curing process and takes a large amount of time in the production process, and the material curing method using a laser requires a large working space for laser generation and reduces the cost of the process. There was a problem that the burden was largely generated.

Accordingly, a material curing method using UV (Ultraviolet), which is relatively less burdensome for production time and production maintenance costs, and enables high-quality output to be obtained, is preferred.

However, in the UV curing method as described above, a UV lamp is used, and there is a problem in that curing cannot be performed properly due to high heat generated when the UV lamp emits light.

Korean Patent Publication No. 10-2015-0066898 for solving this problem relates to a curing apparatus using a UV-LED module, and is disposed on a transfer part for transferring a curing object or an exposure object, and a transfer path of the transfer part, Consisting of a body portion for curing the object to be cured or forming a pattern on the object to be exposed, and a UV light source on the plane of the object to be cured or the object to be exposed passing through the body portion is formed on the upper surface of the body portion. A first light source body mounted with a first light source module consisting of a first UV-LED and a first substrate is disposed to be irradiated, and a UV light source is provided at the edge of the object to be cured passing through the body on both sides of the lower side of the body. A second light source body mounted with a second light source module consisting of a second UV-LED and a second substrate is disposed to irradiate light, and the first and second UV-lights irradiating a UV light source to the first and second light source bodies are disposed. It characterized in that it is configured by arranging at least one heat dissipation unit made of a heat pipe to dissipate heat generated from the LED.

However, in the case of the prior art as described above, it is mainly used to bond to mobile phones, tablets, camera modules, optical sheets, and cases made of a two-dimensional plane, and there is a problem that ultraviolet rays cannot be evenly irradiated on the outer surface of a three-dimensional laminate there was.

An object of the present invention for solving the above problems is to improve the curing performance of the three-dimensional laminate that can improve the strength and shrinkage of the three-dimensional laminate by evenly irradiating ultraviolet rays on the outer surface of the three-dimensional laminate. It is to provide a light curing device.

In addition, another object of the present invention is to reduce the time to cure the three-dimensional laminate by irradiating ultraviolet rays composed of different wavelengths using a plurality of LEDs, and to improve the curing performance of the three-dimensional laminate. It is to provide a light curing device.

In addition, another object of the present invention is to provide an ultraviolet light curing apparatus for improving the curing performance of a three-dimensional laminate that can be dried by evaporating alcohol on the outer surface of a three-dimensional laminate while cooling the LED to irradiate ultraviolet light at a constant wavelength. Is to do.

The ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention to solve the above problems has a housing formed to be opened and closed through a door in the front and empty inside, and is formed in the lower inner side of the housing. It characterized in that it comprises a cradle formed to mount the three-dimensional laminate, and a curing unit formed on the inner side of the housing and curing by irradiating ultraviolet rays on the outer surface of the three-dimensional laminate.

In addition, it is formed on the front of the housing of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention, and by checking the open/close state of the door, power is supplied to the curing unit according to whether the door is opened or closed. It characterized in that it further comprises a detection sensor to or block.

In addition, the curing unit of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention further includes a plurality of LED modules for irradiating ultraviolet rays, and the LED module is an LED having an ultraviolet wavelength of 380 to 390 nm. And, it is characterized in that the 400 ~ 410nm LED is formed alternately.

In addition, the curing unit of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention includes a plurality of LED modules formed to irradiate ultraviolet rays toward the outer surface of the three-dimensional laminate, and the three-dimensional laminate. It is formed on the upper, lower, left, right, and rear surfaces of the body, and reflects the ultraviolet rays irradiated from the LED module to be re-incident to the three-dimensional laminate.

In addition, the cradle of the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate of the present invention rotates and tilts the three-dimensional laminate when the three-dimensional laminate is mounted, and the incident amount of ultraviolet rays irradiated from the curing unit It characterized in that it increases.

In addition, the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention is formed on the rear surface of the housing and includes a cooling fan that cools the curing unit by inhaling outside air, and is formed on the lower surface of the housing. The curing unit further comprises an outlet for discharging the cooled air in a heated state, and the air introduced through the cooling fan is heated while cooling the LED module of the curing unit, and the heated air is the three-dimensional laminate. It is characterized in that the three-dimensional layered body is dried by being moved to the outlet while being in contact with.

In addition, the door of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate of the present invention is formed with an internal confirmation window to check the cured state of the three-dimensional laminate, and the internal confirmation window is It is characterized in that the UV blocking filter is formed so as not to be exposed to.

As described above, according to the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention, it is possible to improve the strength and shrinkage of the three-dimensional laminate by evenly irradiating ultraviolet rays on the outer surface of the three-dimensional laminate. There is an effect.

In addition, according to the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention, the time to cure the three-dimensional laminate is reduced and the curing performance is improved by irradiating ultraviolet rays composed of different wavelengths using a plurality of LEDs. There is an effect that can increase.

In addition, according to the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate according to the present invention, it is possible to evaporate and dry the alcohol on the outer surface of the three-dimensional laminate while cooling the LED to irradiate ultraviolet rays at a certain wavelength. have.

1 is a perspective view showing a curing apparatus using a conventional UV-LED module.
Figure 2 is a perspective view showing the front of the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention.
Figure 3 is an exploded view showing the separation of the curing unit of the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention.
Figure 4 is a perspective view showing the rear and rear surface of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate according to the present invention.
5 is a plan view showing a path through which air is introduced into an ultraviolet light curing apparatus for improving curing performance of a three-dimensional laminate according to the present invention.
6 is a side view showing a path through which air is introduced into an ultraviolet light curing apparatus for improving curing performance of a three-dimensional laminate according to the present invention.
100: housing
110: door
111: internal confirmation window
120: detection sensor
130: cooling fan
140: outlet
200: curing unit
210: reflector
211: entrance hall
212: injection hole
220: first LED module
221: floodlight
222: support ball
230: second LED module
231: diffuser plate
300: cradle
310: rotary motor

Specific features and advantages of the present invention will be described in detail below with reference to the accompanying drawings. Prior to this, when it is determined that a detailed description of functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description will be omitted.

The present invention relates to an ultraviolet light curing apparatus for improving the curing performance of a three-dimensional laminate. When curing a three-dimensional laminate output by a 3D printer, the three-dimensional laminate cured using ultraviolet rays of different wavelengths It relates to an ultraviolet light curing device for improving the curing performance of a three-dimensional laminate to improve strength and shrinkage.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the front of the ultraviolet light curing device for improving the curing performance of the three-dimensional laminate according to the present invention.

As shown in FIG. 2, the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention includes a housing 100 formed to be opened and closed through a door 110 on the front side and empty inside. , A cradle 300 formed on the inner bottom of the housing 100 and formed so that a 3D laminate can be mounted, and a holder 300 formed on the inner side of the housing 100 and cured by irradiating ultraviolet rays on the outer surface of the 3D laminate. It characterized in that it comprises a curing unit (200).

In addition, the cradle 300 is characterized by increasing the incident amount of ultraviolet rays irradiated from the curing unit 200 by rotating and tilting the three-dimensional laminate when the three-dimensional laminate is mounted.

The housing 100 is empty inside so as to accommodate the curing unit 200 and the cradle 300, and after the front is opened, a 3D laminate printed by a 3D printer is placed inside the housing 100. The door 110 is formed so as to be inserted into the interior.

The door 110 is formed so that it can be rotated on one side of the housing 100 so that the front of the housing 100 can be opened and closed, and a power button, an operation button, a time setting button and a Together, a display indicating motion and time is formed.

The curing unit 200 is formed on the inner surface of the housing 100, and irradiates the 3D stacked body with ultraviolet rays from the top, bottom, left, right, and rear directions of the 3D stack mounted on the cradle 300. It will harden.

The cradle 300 is formed on the inner lower surface of the housing 100 and can be rotated by the rotary motor 310 of FIG. 6. When the three-dimensional laminate is mounted on the top, the three-dimensional laminate is formed by the cradle 300. As it rotates, ultraviolet rays can be irradiated on all surfaces of the three-dimensional laminate by the curing unit 200.

In addition, since the cradle 300 can be rotated and tilted at the same time, the three-dimensional laminate can be tilted at a set angle, and the three-dimensional laminate having a complicated shape by rotating the cradle 300 in a tilted state is irradiated with ultraviolet rays without a blind spot. Can be.

At this time, it is preferable that a plurality of protrusions or mounting ends are formed on the upper surface of the mount 300 so that the three-dimensional stack does not slide on the upper surface of the mount 300 in a tilted state, and the mount 300 is formed transparently. It is preferable to allow ultraviolet rays irradiated from the lower surface of the housing 100 to pass through the cradle 300 and enter the three-dimensional laminate.

Through this, ultraviolet rays can be irradiated on all sides without blind spots when curing a three-dimensional laminate having a complex shape.

In addition, it is formed on the front of the housing 100 and further includes a detection sensor 120 that checks the open/close state of the door 110 and supplies or cuts power to the curing unit 200 according to whether the door 110 is opened or closed. Characterized in that.

The detection sensor 120 is used to check the open/closed state of the door 110 and consists of a magnetic sensor, and when the door 110 is closed in close contact with the front of the housing 100, a magnet formed on the inner surface of the door 110 is detected. As the sensor 120 is in close contact with the sensor 120, the detection sensor 120 plays a switching role to supply power to the interior of the housing 100.

That is, only when the door 110 is closed, power is supplied to the inside of the housing 100 by the detection sensor 120 so that the curing unit 200 and the holder 300 are operated, and when the door 110 is opened, it is detected. The power inside the housing 100 is cut off by the sensor 120 to stop the operation of the curing unit 200 and the holder 300.

Therefore, it is possible to prevent ultraviolet rays irradiated by the curing unit 200 from being irradiated to the outside while the door 110 is open, and if the door 110 is opened during curing, the power is cut off and the ultraviolet rays are exposed to the user's skin or eyes. This can be prevented from being irradiated.

In addition, the door 110 is provided with an internal confirmation window 111 to check the cured state of the three-dimensional laminate, and the internal confirmation window 111 is provided with a UV blocking filter so that ultraviolet rays are not exposed to the outside. It is characterized.

The internal confirmation window 111 is for confirming the state of the 3D laminate being cured by the curing unit 200 inside the housing 100 and is formed to penetrate from the front to the rear of the door 110.

In addition, a UV blocking filter for blocking ultraviolet rays irradiated by the curing unit 200 inside the housing 100 is formed in the inner confirmation window 111, and the UV blocking filter allows the user to avoid exposure to ultraviolet rays. 100) It is possible to check the three-dimensional laminate that is cured inside.

3 is an exploded view showing a separate curing unit 200 of an ultraviolet light curing apparatus for improving the curing performance of a three-dimensional laminate according to the present invention.

As shown in Figure 3, the curing unit 200 of the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention is formed so as to irradiate ultraviolet rays toward the outer surface of the three-dimensional laminate. Of the LED module, and a reflective plate 210 formed on the upper, lower, left, right, and rear surfaces of the three-dimensional laminate and reflecting ultraviolet rays irradiated from the LED module to be re-incident to the three-dimensional laminate.

The LED modules 220 and 230 are formed in a plurality so as to irradiate ultraviolet rays from the upper, lower, left, right, and rear surfaces of the three-dimensional laminate, and each of the LED modules 220 and 230 is on the reflector 210 It is attached and fixed.

At this time, since the front surface of the reflector 210 is open, the three-dimensional stack can be inserted into the front surface, and LED modules 220 and 230 are formed on the surfaces other than the front surface to irradiate ultraviolet rays toward the three-dimensional stack body. Is formed to be able to.

In addition, the reflective plate 210 is formed to be spaced apart from the inner surface of the housing 100 of FIG. 2, and the LED modules 220 and 230 are positioned in the space between the housing 100 and the reflecting plate 210. Incident holes 211 penetrating through each surface are formed so that the LED modules 220 and 230 can irradiate ultraviolet rays into the reflector 210.

The reflector 210 is made of stainless steel, so when the LED modules 220 and 230 irradiate ultraviolet rays inside the reflector 210, the reflector 210 reflects ultraviolet rays that have not been absorbed by the 3D stack and re-incidents toward the 3D stack. So that the curing time can be shortened.

That is, since the reflector 210 is formed in a polygonal shape, it is preferable to reflect the ultraviolet rays at multiple angles so that they can be re-incident to the three-dimensional laminate, and the LED modules 220 and 230 are each side of the reflector 210 As it is formed in, it must be able to irradiate ultraviolet rays from various fields.

The LED modules 220 and 230 are composed of a first LED module 220 formed on both side and rear surfaces of the reflector 210 and a second LED module 230 formed on the top and bottom of the reflector 210, respectively.

The first LED module 220 is positioned on the left, right, and rear sides of the reflector 210 to irradiate ultraviolet rays on the side of the 3D stack, and the second LED module 230 is located on the upper and lower portions of the reflector 210. Each is positioned to irradiate ultraviolet rays on the upper and lower surfaces of the 3D laminate.

At this time, since the first LED module 220 has LEDs formed in the vertical direction, when mounted on the reflective plate 210, ultraviolet rays can be irradiated in the vertical direction of the three-dimensional stacked body, and the front surface of the first LED module 220 has a reflective plate ( A support 222 to be coupled to the 210 and a light-transmitting plate 221 formed on the front surface of the support 222 and diffuses the irradiated ultraviolet rays are formed.

The light-transmitting plate 221 is for diffusing light irradiated from the LED so that ultraviolet rays can be incident on the three-dimensional laminate, and is formed transparently, and a diffusion lens is disposed corresponding to the position where the LED is formed.

The support 222 is formed with grooves on the front and rear sides so that the first LED module 220 is inserted in the rear side and the floodlight plate 221 is inserted in the front side, and the center is penetrated so that the LED can pass. have.

In addition, the support tool 222 is coupled to the outer surface of the reflective plate 210 to fix the positions of the first LED module 220 and the light transmitting plate 221.

The second LED module 230 is formed on the upper and lower portions of the reflector 210 and has a circular or semi-circular LED, and is irradiated with ultraviolet rays through the incident hole 211 of the reflector 210, 300) to cure the upper and lower surfaces of the 3D laminate.

At this time, a diffusion plate 231 is formed between the second LED module 230 and the reflection plate 210 in order to fix the second LED module 230 to the upper and lower portions of the reflecting plate 210, and the diffusion plate 231 has an LED A lens is formed for diffusing the ultraviolet rays irradiated from.

In addition, since the support 222 and the diffusion plate 231 are formed of aluminum or copper, which is easy to absorb heat, it can also serve as a heat sink to absorb heat generated from the first LED module 220 and release it to the outside. In this case, it is preferable that a plurality of grooves and projections are formed on the outer surfaces of the support tool 222 and the diffusion plate 231.

In addition, the support 222 and the diffusion plate 231 transfer the heat generated from the first LED module 220 and the second LED module 230 to the reflector 210, so that the first LED module by the reflector 210 having a large area. It is possible to quickly cool the 220 and the second LED module 230.

In addition, the curing unit 200 further includes a plurality of LED modules 220 and 230 for irradiating ultraviolet rays, and the LED modules 220 and 230 include an LED having an ultraviolet wavelength of 380 to 390 nm and an LED of 400 to 410 nm. It is characterized in that it is formed alternately.

The LEDs formed in the first LED module 220 and the second LED module 230 are alternately irradiated with LEDs that irradiate different wavelengths in order to form a UV lamp and a curing effect similarly, so that different types of UV wavelengths are irradiated to the three-dimensional stack. Will be done.

The first wavelength irradiated by the LED modules 220 and 230 is composed of 380 to 390 nm, the second wavelength is composed of 400 to 410 nm, and the ideal wavelength alternates between the first wavelength of 385 nm and the second wavelength of 405 nm. It is preferable to form the LED module (220, 230).

The first and second wavelengths consist of a wavelength band with a high absorbance of the photoinitiator mixed in the resin when the 3D printer outputs the 3D laminate, so the two wavelengths increase the curing speed of the photoinitiator and increase the strength when cured. There will be.

4 is a perspective view showing the rear and rear surfaces of an ultraviolet light curing apparatus for improving the curing performance of a three-dimensional laminate according to the present invention, and FIG. 5 is an ultraviolet ray for improving the curing performance of the three-dimensional laminate according to the present invention. It is a plan view showing the path through which air flows into the light curing device. 6 is a side view showing a path through which air is introduced into the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention.

4 to 6, the ultraviolet light curing device for improving the curing performance of the dimensional laminate according to the present invention is formed on the rear surface of the housing 100 and cools the curing unit 200 by sucking outside air. It further comprises a cooling fan 130 to allow, and an outlet 140 formed on the lower surface of the housing 100 to discharge the air that has cooled the curing unit 200 in a heated state, and the cooling fan 130 The air introduced through is heated while cooling the LED modules 220 and 230 of the curing unit 200, and the heated air is moved to the outlet 140 while being in contact with the 3D stack to dry the 3D stack. It is characterized.

The cooling fan 130 is formed on the rear side of the housing 100 and cools the heat generated from the LED of the curing unit 200 by inhaling external air into the housing 100, thereby reducing the output of the LED due to high temperature. Is formed to prevent it.

At this time, some of the air sucked by the cooling fan 130 moves along the outer surface of the reflector 210 formed to be spaced apart from the inner surface of the housing 100 as shown in FIG. 5, and part of the air is moved along the outer surface of the reflector 210 as shown in FIG. Will be moved to the top of.

At this time, the air is moved while being in direct contact with the first LED module 220 and the second LED module 230, absorbs heat from the first LED module 220 and the second LED module 230 by convective heat transfer, and is heated. 220) and the second LED module 230 are cooled.

In addition, the reflector 210 in contact with the first LED module 220 and the second LED module 230 also acts as a heat sink to absorb heat generated from the first LED module 220 and the second LED module 230. In this case, as the air moves, the area in contact with the reflector 210 increases, so that the heat absorption speed increases, so that the first LED module 220 and the second LED module 230 can be cooled more efficiently.

In addition, a plurality of spray holes 212 are formed in the reflector 210, and the air introduced between the housing 100 and the reflector 210 by the cooling fan 130 is transferred to the housing 100 through the spray hole 212. After spraying in the direction of the cradle 300 formed in the lower center of the reflector 210, it is discharged to the discharge port 140 through the lower portion of the reflector 210.

At this time, the three-dimensional stack mounted on the cradle 300 cools the first LED module 220 and the second LED module 230 while the heated air moves in direct contact with each other, so that the air is absorbed on the outer surface of the three-dimensional stack. I can evaporate the alcohol and dry it.

That is, the air sucked by the cooling fan 130 is moved between the housing 100 and the reflector 210 to be heated while primarily cooling the first LED module 220 and the second LED module 230. Air is blown toward the center of the mounting plate to dry the three-dimensional laminate.

After that, the air is discharged to the outside through the outlet 140 formed under the housing 100 through the injection hole 212 formed under the holder 300.

As described above, according to the ultraviolet light curing apparatus for improving the curing performance of the three-dimensional laminate according to the present invention, it is possible to improve the strength and shrinkage of the three-dimensional laminate by evenly irradiating ultraviolet rays on the outer surface of the three-dimensional laminate. In addition, by irradiating ultraviolet rays composed of different wavelengths using a plurality of LEDs, it is possible to reduce the curing time and increase the curing performance of the 3D stacked body, and cool the LEDs to irradiate ultraviolet rays at a certain wavelength. It has the effect of drying by evaporating the alcohol on the outside.

As described above, the present invention has been described with a focus on preferred embodiments, but a person having ordinary knowledge in the technical field to which the present invention pertains can variously modify the present invention within the scope not departing from the technical spirit and scope described in the claims of the present invention. It can be modified or modified accordingly. Accordingly, the scope of the invention should be construed by the claims set forth to include examples of such many variations.

Claims (7)

A housing formed to be empty inside and open and close through a door;
A cradle formed under the inner side of the housing and configured to mount a three-dimensional stack;
Includes; a curing unit formed on the inner surface of the housing and curing by irradiating ultraviolet rays on the outer surface of the three-dimensional laminate,
The cradle is rotated and tilted when the three-dimensional laminate is mounted so that ultraviolet rays irradiated by the curing unit can be irradiated to all surfaces of the three-dimensional laminate,
The curing unit
A plurality of LED modules formed to irradiate ultraviolet rays toward the outer surface of the three-dimensional laminate;
Includes; a reflective plate formed on the upper, lower, left, right, and rear surfaces of the three-dimensional laminate and reflecting ultraviolet rays irradiated from the LED module so as to be re-incident to the three-dimensional laminate; and
The LED module is
A first LED module positioned on the left side, the right side, and the rear side of the reflecting plate to irradiate ultraviolet rays onto the side surface of the three-dimensional laminate;
Consists of; a second LED module positioned on the upper and lower portions of the reflector, respectively, to irradiate ultraviolet rays on the upper and lower surfaces of the three-dimensional laminate,
The cradle is rotated and tilted when the three-dimensional laminate is mounted so that ultraviolet rays irradiated by the curing unit can be irradiated to all surfaces of the three-dimensional laminate,
The upper surface of the mount further includes a plurality of protrusions or mounting steps so that the three-dimensional stacked body does not slide in a tilted state,
The cradle is formed to be transparent so that ultraviolet rays irradiated from the lower surface of the housing can be incident on the three-dimensional laminate.
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate. The method of claim 1,
And a detection sensor formed on the front surface of the housing to check the open/close state of the door, and supply or cut off power to the curing unit according to whether the door is open or closed.
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate. The method of claim 1,
The curing unit further includes a plurality of LED modules for irradiating ultraviolet rays,
The LED module is characterized in that formed by alternating an LED having an ultraviolet wavelength of 380 to 390 nm and an LED of 400 to 410 nm.
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate. delete The method of claim 1,
When the three-dimensional laminate is mounted, the cradle rotates and tilts the three-dimensional laminate to increase the incident amount of ultraviolet rays irradiated from the curing unit.
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate. The method of claim 1,
A cooling fan formed on the rear surface of the housing and cooling the curing unit by sucking outside air;
An outlet formed on the lower surface of the housing and configured to discharge the air that has cooled the curing unit in a heated state;
The air introduced through the cooling fan is heated while cooling the LED module of the curing unit, and the heated air is moved to the outlet while being in contact with the three-dimensional laminate to dry the three-dimensional laminate.
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate. The method of claim 1,
The door is provided with an internal confirmation window to check the cured state of the three-dimensional laminate,
The inner confirmation window is characterized in that the ultraviolet ray blocking filter;
Ultraviolet light curing device to improve the curing performance of the three-dimensional laminate.

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