KR102643109B1 - Ultraviolet curing apparatus, bending protect layer forming system and method for ultraviolet curing - Google Patents

Abstract

The present invention provides an ultraviolet curing device, a banding protection layer forming system, and an ultraviolet curing method that can replace a halogen lamp through an ultraviolet LED array comprising a plurality of ultraviolet LEDs arranged in a first direction and having different peak wavelengths.
An ultraviolet curing device according to an embodiment of the present invention includes a first ultraviolet LED array including a plurality of first ultraviolet LEDs arranged in a row in a first direction; And a second ultraviolet LED array including a plurality of second ultraviolet LEDs arranged in a row in the first direction, wherein the peak wavelength of the light emitted from the first ultraviolet LED is the peak wavelength of the light emitted from the second ultraviolet LED. It can be longer than the wavelength.

Description

Ultraviolet curing apparatus, bending protect layer forming system and method for ultraviolet curing {Ultraviolet curing apparatus, bending protect layer forming system and method for ultraviolet curing}

The present invention relates to an ultraviolet curing device, a banding protective layer forming system, and an ultraviolet curing method. More specifically, it relates to an ultraviolet curing device, a banding protective layer forming system, and an ultraviolet curing method that can replace a halogen lamp.

An ultraviolet curing device is a device that improves the surface hardness of a product by using a chemical reaction in which the cured object is instantaneously hardened when ultraviolet rays are irradiated to the cured object. As the ultraviolet curing process is essential for product production, ultraviolet curing devices are used in various technological fields such as semiconductors, electronics, medical care, and communications.

Conventional ultraviolet curing devices used halogen lamps as ultraviolet ray emission sources. However, more than 80% of halogen lamps emit visible light, and less than 20% of the ultraviolet rays used to cure the cured material are emitted. Therefore, in order to secure a large amount of ultraviolet rays necessary for ultraviolet curing, a high-capacity and expensive lamp of about 1,500 to 30,000 W is used, resulting in the cost of installing a separate facility for electricity supply and excessive power costs. Additionally, halogen lamps generate high-temperature heat, which causes the problem of deforming the shape of the object to be cured or even burning it due to the high-temperature heat. In addition, halogen lamps cause environmental pollution by mercury when disposed of.

Therefore, a technology is needed that can replace the halogen lamp used in ultraviolet curing devices to lower facility installation costs and power costs, suppress high-temperature heat generation, and reduce environmental pollution.

Public Patent No. 2004-0034086

The present invention provides an ultraviolet curing device, a banding protection layer forming system, and an ultraviolet curing method that can replace a halogen lamp through an ultraviolet LED array comprising a plurality of ultraviolet LEDs arranged in a first direction and having different peak wavelengths.

An ultraviolet curing device according to an embodiment of the present invention includes a first ultraviolet LED array including a plurality of first ultraviolet LEDs arranged in a row in a first direction; And a second ultraviolet LED array including a plurality of second ultraviolet LEDs arranged in a row in the first direction, wherein the peak wavelength of the light emitted from the first ultraviolet LED is the peak wavelength of the light emitted from the second ultraviolet LED. It can be longer than the wavelength.

The first ultraviolet LED array may be provided in plurality on both sides of the second ultraviolet LED array.

The first ultraviolet LED array may be symmetrical with respect to the second ultraviolet LED array.

The amount of light emitted from the first ultraviolet LED array may be greater than the amount of light emitted from the second ultraviolet LED array.

The peak wavelength of the light emitted from the first ultraviolet LED may be 355 to 385 nm, and the peak wavelength of the light emitted from the second ultraviolet LED may be 300 to 330 nm.

It may further include a lens-type light guide plate that receives light emitted from the first ultraviolet LED array and the second ultraviolet LED array and provides mixed light thereof to the object to be cured.

It further includes a light measuring unit that measures the illuminance of light emitted from the first ultraviolet LED array or the second ultraviolet LED array, wherein the light measuring unit includes: an optical fiber that forms an optical path and passes light; a reflector disposed at one end of the optical fiber to reflect light emitted from the first ultraviolet LED array or the second ultraviolet LED array to the optical fiber; and an optical sensor disposed at the other end of the optical fiber to measure the illuminance of light passing through the optical fiber.

It may further include a control unit that controls the amount of light in at least one of each row of the first ultraviolet LED array and the second ultraviolet LED array using the illuminance of the light measured by the light measurement unit.

a support portion provided on one side of the first ultraviolet LED array and the second ultraviolet LED array to support the first ultraviolet LED array and the second ultraviolet LED array; And a cooling unit provided on the other side of the support unit to cool the heat generated from the first ultraviolet LED and the second ultraviolet LED. The optical fiber of the light measurement unit may pass through the support unit. .

It may further include a moving part that moves the cured object in the first direction, and the cured object may be exposed to light emitted from the first ultraviolet LED array and the second ultraviolet LED array while moving.

A banding protection layer forming system according to another embodiment of the present invention includes an alignment device that provides a movement path for the display panel and aligns the display panel with respect to a rail extending in a first direction; an applicator for partially applying a dispenser liquid for a banding protection layer to one surface of the display panel moving along the rail; and an ultraviolet curing device according to an embodiment of the present invention that irradiates light to the dispenser liquid for the banding protection layer applied to the display panel moving along the rail.

An ultraviolet curing method according to another embodiment of the present invention includes a process in which a moving part moves a cured object in a first direction; And providing a first ultraviolet light LED array having a plurality of first ultraviolet LEDs arranged in a row in the first direction and a second ultraviolet LED array having a plurality of second ultraviolet LEDs arranged in a row in the first direction. A curing device may include a process of irradiating light to the object to be cured, wherein the peak wavelength of the light emitted from the first ultraviolet LED may be longer than the peak wavelength of the light emitted from the second ultraviolet LED.

The first ultraviolet LED array is provided in plurality on both sides of the second ultraviolet LED array and may be symmetrical to each other.

The amount of light emitted from the first ultraviolet LED array may be greater than the amount of light emitted from the second ultraviolet LED array.

The peak wavelength of the light emitted from the first ultraviolet LED may be 355 to 385 nm, and the peak wavelength of the light emitted from the second ultraviolet LED may be 300 to 330 nm.

The ultraviolet curing device according to an embodiment of the present invention includes a first ultraviolet light LED array having a plurality of first ultraviolet LEDs and a second ultraviolet light LED array having a plurality of second ultraviolet LEDs, and can replace a halogen lamp. there is. In addition, by providing the first ultraviolet light LED and the second ultraviolet light LED, the object to be cured can be efficiently cured using a specific peak wavelength. At this time, the peak wavelength of the light emitted from the first ultraviolet LED is longer than the peak wavelength of the light emitted from the second ultraviolet LED, and the light emitted from the first ultraviolet LED penetrates deep into the interior of the object to be cured due to its long wavelength, curing the interior. You can do it. In addition, the light emitted from the second ultraviolet LED can harden the surface of the cured object due to its short wavelength and maintain the applied state of the cured object without deformation. That is, the ultraviolet curing device of the present invention can effectively cure the surface and interior of the object to be cured. Here, since the amount of light emitted from the first ultraviolet LED array is greater than the amount of light emitted from the second LED array, the interior of the object to be cured is sufficiently cured, so that the surface and interior can be uniformly cured. A plurality of first ultraviolet LED arrays are provided on both sides around the second ultraviolet LED array and are symmetrical to each other, so that uniform light can be irradiated to the object to be cured. In addition, the ultraviolet curing device of the present invention further includes an optical measurement unit including an optical fiber, a reflector, and an optical sensor, and can measure emitted light by ensuring stability by preventing deterioration due to high temperature. And the ultraviolet curing device of the present invention further includes a control unit, and can control the amount of light of at least one of each row of the first ultraviolet LED array and the second ultraviolet LED array using the illuminance of the light measured by the light measuring unit. . In addition, the ultraviolet curing device of the present invention further includes a cooling unit, and can ensure stability by cooling the heat caused by light emitted from the first ultraviolet LED and the second ultraviolet LED.

And the banding protective layer forming system includes an alignment device, an application device, and an ultraviolet curing device of the present invention, and after aligning the display panel, the display panel is moved along a rail extending in the first direction to apply and cure the dispenser liquid for the banding protective layer. You can. Due to this, the application position of the dispenser liquid for the banding protective layer corresponds to the light irradiation position for the applied dispenser liquid for the banding protective layer, making it possible to effectively form a banding protective layer. At this time, each of the first ultraviolet LED array and the second ultraviolet LED array of the ultraviolet curing device of the present invention has a shape extending in the first direction, so that light can be irradiated specifically to the banding protection layer.

In addition, the ultraviolet curing method involves irradiating light to the object to be cured through a first ultraviolet light LED array having a plurality of first ultraviolet LEDs and a second ultraviolet light LED array having a plurality of second ultraviolet LEDs, using a halogen lamp. can be replaced. In addition, since the peak wavelength of the light emitted from the first ultraviolet LED is different from the peak wavelength of the light emitted from the second ultraviolet LED, the surface and interior of the object to be cured can be effectively cured.

1 is a cross-sectional view showing an ultraviolet curing device according to an embodiment of the present invention.
Figure 2 is a graph showing the peak wavelength of light emitted from an ultraviolet curing device according to an embodiment of the present invention.
Figure 3 is a perspective view showing the ultraviolet curing device according to an embodiment of the present invention cut in the vertical direction.
Figure 4 is a cross-sectional view showing the light measurement unit of the ultraviolet curing device according to an embodiment of the present invention.
Figure 5 is a perspective view showing an ultraviolet curing device according to an embodiment of the invention.
Figure 6 is a perspective view showing a banding protection layer forming system according to another embodiment of the present invention.
Figure 7 is a flow chart showing an ultraviolet curing method according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the attached drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various different forms. These embodiments only serve to ensure that the disclosure of the present invention is complete and to those skilled in the art to fully convey the scope of the invention. This is provided to inform you. During the description, the same reference numerals are assigned to the same components, and the drawings may be partially exaggerated in size to accurately describe embodiments of the present invention. In the drawings, the same reference numerals refer to the same elements.

Figure 1 is a cross-sectional view showing an ultraviolet curing device 100 according to an embodiment of the present invention.

Referring to FIG. 1, the ultraviolet curing device ₁₀₀ according to an embodiment of the present invention includes a first ultraviolet LED array ( 110); And a second ultraviolet LED array 120 including a plurality of second ultraviolet LEDs 121 arranged in a row in the first direction (D ₁ ), wherein the light emitted from the first ultraviolet LED 111 The peak wavelength may be longer than the peak wavelength of light emitted from the second ultraviolet LED 121.

The first ultraviolet LED array 110 may emit light by providing a plurality of first ultraviolet LEDs 111 arranged in a row in the first direction D ₁ . At this time, the first ultraviolet LED array 110 forms a plurality of rows, thereby increasing the amount of light emitted from the first ultraviolet LED array 110.

The second ultraviolet LED array 120 may emit light by providing a plurality of second ultraviolet LEDs 121 arranged in a row in the first direction (D ₁ ). At this time, the second ultraviolet LED array 120 forms a plurality of rows, thereby increasing the amount of light emitted from the second ultraviolet LED array 120.

In this way, the ultraviolet curing device 100 of the present invention includes a plurality of first ultraviolet LEDs 111 forming a row in the first direction (D ₁ ) and a plurality of second ultraviolet rays forming a row in the first direction (D ₁ ). By providing the LED 121, it may be extended in the first direction (D ₁ ). For this reason, as will be described later, when the ultraviolet curing device of the present invention is applied to a banding protective layer forming system, light can be irradiated in a manner specialized for the shape of the banding protective layer.

Here, the peak wavelength of the light emitted from the first ultraviolet LED 111 may be longer than the peak wavelength of the light emitted from the second ultraviolet LED 121. That is, the ultraviolet curing device 100 of the present invention may be provided with a plurality of ultraviolet LEDs having different peak wavelengths. For example, the peak wavelength of light emitted from the first ultraviolet LED 111 may be 360 nm, and the peak wavelength of light emitted from the second ultraviolet LED 121 may be 310 nm. For this reason, the peak wavelength of the light emitted from the first ultraviolet LED 111 penetrates deep into the interior of the object to be cured (d) due to its long wavelength, thereby allowing the interior of the object to be cured (d) to be cured. In addition, the peak wavelength of the light emitted from the second ultraviolet LED 121 has a short wavelength, so the surface of the cured object d can be cured and the coated state of the cured object d can be maintained without deformation. Accordingly, the ultraviolet curing device 100 of the present invention can effectively cure the surface and interior of the object to be cured (d).

This ultraviolet curing device 100 can improve the surface hardness of a product by using a chemical reaction in which the cured object (d) is instantly hardened when ultraviolet rays are irradiated to the cured object (d). As the ultraviolet curing process is essential for product production, the ultraviolet curing device 100 is used in various technological fields such as semiconductors, electronics, medical care, and communications.

Conventional ultraviolet curing devices used halogen lamps as ultraviolet ray emission sources. However, about 80% or more of the halogen lamp is emitted as visible light, and less than 20% of the ultraviolet rays used to cure the object (d) are emitted. Therefore, in order to secure a large amount of ultraviolet rays necessary for ultraviolet curing, a high-capacity and expensive lamp of about 1,500 to 30,000 W is used, resulting in the cost of installing a separate facility for electricity supply and excessive power costs. Additionally, halogen lamps generate high-temperature heat, which causes the problem of deforming the shape of the object to be cured (d) or even burning it due to the high-temperature heat. In addition, halogen lamps cause environmental pollution by mercury when disposed of.

However, the ultraviolet curing device 100 of the present invention uses a plurality of LEDs to replace halogen lamps, thereby lowering facility installation costs and power costs, suppressing high-temperature heat generation, and reducing environmental pollution.

For example, the ultraviolet curing device 100 of the present invention can be applied to the bending protection layer process equipment of an OLED display, which cures the applied dispenser liquid (d) for the bending protection layer with ultraviolet rays. . In particular, the ultraviolet curing device 100 of the present invention can be applied to a potting process, which is one of the module processes. At this time, the ultraviolet curing device 100 of the present invention is a device that forms a coating layer to protect the display panel (p) from moisture permeability of fine cracks that may occur when bending the display panel (p). It can be. Here, the potting process may be performed through plasma, dispensing, UV curing, and inspection processes.

A conventional ultraviolet curing device used a halogen lamp with a peak wavelength in the range of 200 to 420 nm to cure the dispenser liquid (d) for the banding protection layer. These halogen lamps have disadvantages in that output control is difficult and wavelength selection is difficult. On the other hand, the ultraviolet curing device 100 of the present invention uses a plurality of LEDs that emit a specific wavelength to emit peak wavelengths other than 365 nm, so that the banding protective layer is used at a wavelength specialized for the dispenser liquid (d) for the banding protective layer. The dispenser liquid (d) can be hardened. That is, the ultraviolet curing device 100 of the present invention may have flexibility in selecting a wavelength. Additionally, the ultraviolet curing device 100 of the present invention may be capable of output conversion of 10 to 100%.

Conventional ultraviolet curing devices were connected to optical fibers made of metal, making bending difficult and movable installation difficult. On the other hand, the ultraviolet curing device 100 of the present invention can be installed movably by being connected to a flexible power cable. Because of this, the ultraviolet curing device 100 of the present invention can control the position where light is irradiated by controlling the fixed position.

The first ultraviolet LED array 110 may be provided in plurality on both sides of the second ultraviolet LED array 120 as the center.

A plurality of the first ultraviolet LED array 110 is provided on both sides around the second ultraviolet LED array 120, so that light can be uniformly irradiated to the object to be cured (d). Here, the peak wavelength of the light emitted from the first ultraviolet LED 111 and the peak wavelength of the light emitted from the second ultraviolet LED 121 may be different from each other. For this reason, the ultraviolet curing device 100 is better when the first ultraviolet LED array 110 is provided on both sides around the second ultraviolet LED array 120 than when the plurality of ultraviolet LED arrays 110 are not provided on both sides. More uniform light can be emitted.

The first ultraviolet LED array 110 may be symmetrical with respect to the second ultraviolet LED array 120.

Since the first ultraviolet LED array 110 is symmetrical with respect to the second ultraviolet LED array 120, light can be uniformly irradiated to the object to be cured d. For example, when the cured body (d) is a dispenser liquid (d) for a banding protection layer applied to be described later and is extended in the first direction (D ₁ ), the ultraviolet rays emitted from the first ultraviolet LED array 110 Light is irradiated uniformly on both sides of the object to be cured (d), allowing the object to be cured (d) to be cured efficiently. At this time, the first ultraviolet LED array 110 is symmetrical with respect to the second ultraviolet LED array 120, so that the light emitted from them passes through the lens-type light guide plate 130 and is then efficiently transmitted as described later. It can be concentrated. Here, the lens-type light guide plate 130 may correspond to the position of the second ultraviolet LED array 120, and the distance from each of the first ultraviolet LED arrays 110 may correspond to each other.

The amount of light emitted from the first ultraviolet LED array 110 may be greater than the amount of light emitted from the second ultraviolet LED array 120.

Since the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, when light is irradiated to the object to be cured (d), the surface of the object to be cured (d) and The interior can be hardened evenly. Here, the first ultraviolet LED 111 of the first ultraviolet LED array 110 hardens the inside of the object to be cured (d), as described later, and the second ultraviolet LED of the second ultraviolet LED array 120 ( 121) can harden the surface of the object to be cured (d). When curing the object (d), the interior has a larger volume than the surface, so more energy and time may be needed to cure the interior than the surface of the object (d). At this time, in the ultraviolet curing device 100 of the present invention, the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, so that the cured object (d) When irradiated with light, the inside of the object to be cured (d) can be sufficiently cured. For this reason, the ultraviolet curing device 100 of the present invention can uniformly and efficiently cure the surface and interior of the object to be cured (d).

Here, the first ultraviolet LED array 110 has a larger number of columns than the second ultraviolet LED array 120, so the amount of light emitted may be greater. Alternatively, the amount of light emitted by the first ultraviolet LED 111 is adjusted to be greater than that of the second ultraviolet LED 121, so that the first ultraviolet LED array 110 emits more light than the second ultraviolet LED array 120. The amount of light emitted can be adjusted to a greater extent.

The peak wavelength of the light emitted from the first ultraviolet LED 111 may be 355 to 385 nm, and the peak wavelength of the light emitted from the second ultraviolet LED 121 may be 300 to 330 nm.

Since the peak wavelength of the light emitted from the first ultraviolet LED 111 is 355 to 385 nm, when light is irradiated to the object to be cured (d), it penetrates deep into the interior of the object to be cured (d) due to the long wavelength. ) can harden the interior. For example, the peak wavelength of light emitted from the first ultraviolet LED 111 may be 365 nm.

Since the peak wavelength of the light emitted from the second ultraviolet LED 121 is 300 to 330 nm, the surface of the cured object (d) is cured due to the short wavelength when light is irradiated to the cured object (d) without deformation ( The application state of d) can be maintained. For example, the peak wavelength of light emitted from the second ultraviolet LED 121 may be 310 nm.

In this way, the ultraviolet curing device 100 of the present invention has a peak wavelength of light emitted from the first ultraviolet LED 111 of 355 to 385 nm and a peak wavelength of light emitted from the second ultraviolet LED 121 of 300 to 330 nm. As a result, the surface and interior of the object to be cured (d) can be effectively cured. In particular, since the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, when light is irradiated to the object to be cured (d), The surface and interior can be hardened uniformly. At this time, the object to be cured (d) may be an acrylic resin.

Figure 2 is a graph showing the peak wavelength of light emitted from the ultraviolet curing device 100 according to an embodiment of the present invention, and Figure 2(a) shows the peak wavelength of light emitted from the first ultraviolet LED array 110. 2(b) shows the peak wavelength of light emitted from the second ultraviolet LED array 120.

2(a) and 2(b), the peak wavelength of the light emitted from the first ultraviolet LED array 110 is 355 to 385 nm, and the peak wavelength of the light emitted from the second ultraviolet LED array 120 is It can be confirmed that it is 300 to 330 nm. In particular, it can be seen that the peak wavelength of the light emitted from the first ultraviolet LED array 110 is 365 nm (a), and the peak wavelength of the light emitted from the second ultraviolet LED array 120 is 310 nm (b).

It may further include a lens-type light guide plate 130 that receives the light emitted from the first ultraviolet LED array 110 and the second ultraviolet LED array 120 and provides the mixed light to the object to be cured (d). .

The lens-type light guide plate 130 receives the light emitted from the first ultraviolet LED array 110 and the second ultraviolet LED array 120 and provides mixed light thereof to the object to be cured (d), d) Light can be irradiated uniformly. At this time, the lens-type light guide plate 130 evenly diffuses the light by converting the point light source emitted from the first ultraviolet LED 111 and the second ultraviolet LED 121 into a surface light source, so that the mixed light thereof can be made uniform. there is.

In addition, the lens-type light guide plate 130 receives the light emitted from the first ultraviolet LED array 110 and the second ultraviolet LED array 120 and focuses the mixed light on the object to be cured (d). . For this reason, the ultraviolet curing device 100 of the present invention condenses and irradiates light to the object to be cured (d) extending in one direction, thereby increasing curing efficiency. To this end, the first ultraviolet LED array 110 is symmetrical with respect to the second ultraviolet LED array 120, so that the light emitted from them passes through the lens-type light guide plate 130 and is then efficiently transmitted. It can be concentrated. Here, the lens-type light guide plate 130 may correspond to the position of the second ultraviolet LED array 120, and the distance from each of the first ultraviolet LED arrays 110 may correspond to each other.

The lens-type light guide plate 130 may be in the form of a plate or rod extending long in the first direction D ₁ .

It further includes an optical measuring unit 140 that measures the illuminance of light emitted from the first ultraviolet LED array 110 or the second ultraviolet LED array 120, and the optical measuring unit 140 forms an optical path. an optical fiber 141 that allows light to pass through; A reflector 142 disposed at one end of the optical fiber 141 to reflect light emitted from the first ultraviolet LED array 110 or the second ultraviolet LED array 120 to the optical fiber 141; and an optical sensor 143 disposed at the other end of the optical fiber 141 to measure the illuminance of light passing through the optical fiber 141.

The light measurement unit 140 measures the illuminance of light emitted from the first ultraviolet LED array 110 or the second ultraviolet LED array 120 in real time, thereby measuring the first ultraviolet LED array 111 or the second ultraviolet LED array 120. The damage at (121) can be identified. That is, the light measuring unit 140 can prevent the non-curing object (d) from being cured. Here, the light measuring unit 140 may be provided on at least one of the first ultraviolet LED array 110 or the second ultraviolet LED array 120. Alternatively, a plurality of light measurement units 140 may be provided to each of the first ultraviolet LED array 110 and the second ultraviolet LED array 120. Alternatively, at least one light measurement unit 140 may be provided in each row of the first ultraviolet LED array 110 and the second ultraviolet LED array 120. The optical measurement unit 140 may include an optical fiber 141, a reflector 142, and an optical sensor 143.

The optical fiber 141 forms an optical path that allows total reflection of light to pass through, allowing light to be transmitted without loss. At this time, the optical fiber 141 is an optical fiber and can ensure reliability even at high temperatures (about 400°C).

The reflector 142 is disposed at one end of the optical fiber 141 and can reflect light emitted from the first ultraviolet LED array 110 or the second ultraviolet LED array 120 into the optical fiber 141. .

The optical sensor 143 is disposed at the other end of the optical fiber 141 and can measure the illuminance of light passing through the optical fiber 141. Because of this, the optical sensor 143 measures the light passing through the optical fiber 141, thereby preventing deterioration due to high temperature and ensuring stability.

That is, the light measurement unit 140 reflects the light emitted from the first ultraviolet LED array 110 or the second ultraviolet LED array 120 by the reflector 142 and passes it through the optical fiber 141. Afterwards, the illuminance of light passing through the optical fiber 141 can be measured using the optical sensor 143. In this way, the optical sensor 143 of the optical measurement unit 140 measures light at a distance from the first ultraviolet LED 111 and the second ultraviolet LED 121, thereby ensuring stability by preventing deterioration due to high temperature. You can.

A control unit that controls the amount of light in at least one of each row of the first ultraviolet LED array 110 and the second ultraviolet LED array 120 using the illuminance of the light measured by the light measurement unit 140. It can be included.

The control unit may control the amount of light of at least one of each row of the first ultraviolet LED array 110 and the second ultraviolet LED array 120 using the illuminance of the light measured by the light measurement unit 140. there is. At this time, the amount of light in each row of the first ultraviolet LED array 110 and the second ultraviolet LED array 120 can be controlled by adjusting the current.

For example, when the illuminance of light measured by the light measurement unit 140 is less than a preset value, the control unit may increase the amount of heat provided by the light measurement unit 140. Conversely, when the illuminance of light measured by the light measurement unit 140 is greater than a preset value, the control unit may reduce the amount of heat provided by the light measurement unit 140. Additionally, the control unit may control the amount of light emitted from the first ultraviolet LED array 110 to be greater than the amount of light emitted from the second ultraviolet LED array 120. Because of this, when light is irradiated to the object to be cured (d) through the ultraviolet curing device 100 of the present invention, the surface and interior of the object to be cured (d) can be uniformly cured.

The first ultraviolet LED array 110 and the second ultraviolet LED array 120 are provided on one side, and a support portion 150 supports the first ultraviolet LED array 110 and the second ultraviolet LED array 120. ); And a cooling unit 160 provided on the other side of the support unit 150 to cool the heat generated from the first ultraviolet LED 111 and the second ultraviolet LED 121, wherein the light The optical fiber 141 of the measurement unit 140 may pass through the support part 150.

The support portion 150 is provided with the first ultraviolet LED array 110 and the second ultraviolet LED array 120 on one side, and the first ultraviolet LED array 110 and the second ultraviolet LED array 120 can be stably supported.

The cooling unit 160 is provided on the other side of the support unit 150 and can cool the heat generated from the first ultraviolet LED 111 and the second ultraviolet LED 121. At this time, the cooling unit 160 may cool the heat generated from the first ultraviolet LED 111 and the second ultraviolet LED 121 by air cooling or water cooling. For example, the cooling unit 160 may include a heat sink 161 or a fan 162. Here, the cooling unit 160 may not contact the other side of the support unit 150.

At this time, the optical fiber 141 of the light measurement unit 140 may pass through the support part 150 and be supported by the support part 150. That is, the optical sensor 143 of the optical measurement unit 140 may be provided at a location close to the other side of the support unit 150. For this reason, the optical sensor 143 of the optical measurement unit 140 cools the heat caused by the light passing through the optical fiber 141 through the cooling unit 160 provided on the other side of the support unit 150. This can ensure stability. That is, the cooling unit 160 can prevent the optical sensor 143 of the optical measurement unit 140 from being heated.

Figure 3 is a perspective view showing the ultraviolet curing device 100 according to an embodiment of the present invention cut in the vertical direction.

Looking at FIG. 3, it can be seen that the support portion 150 supports the first ultraviolet LED array 110 and the second ultraviolet LED array 120 provided on one side. At this time, it can be confirmed that each of the first ultraviolet LED array 110 and the second ultraviolet LED array 120 extends in the first direction (D ₁ ). It can be seen that a cooling unit 160 including a heat sink 161 and a fan 162 is provided on the other side of the support unit 150. In addition, it can be confirmed that light emitted from the first ultraviolet LED array 110 and the second ultraviolet LED array 120 passes through the lens-type light guide plate 130.

Figure 4 is a cross-sectional view showing the light measurement unit 140 of the ultraviolet curing device 100 according to an embodiment of the present invention.

Looking at FIG. 4, it can be seen that a reflector 142 is placed on one end of the optical fiber 141 and an optical sensor 143 is placed on the other end of the optical fiber 141. And the light emitted from the first ultraviolet LED 111 or the second ultraviolet LED 121 is reflected by the reflector 142 and passes through the optical fiber 141, and the light passing through the optical fiber 141 is transmitted to the optical sensor 143. It can be seen that it is measured by . And it can be confirmed that the first ultraviolet LED 111 or the second ultraviolet LED 121 and the optical sensor 143 are provided spaced apart from each other. Additionally, it can be seen that the optical fiber 141 penetrates the support part 150.

It further includes a moving part that moves the cured object (d) in the first direction (D ₁ ), and while the cured object (d) moves, the first ultraviolet LED array 110 and the second ultraviolet LED array 120 ) can be exposed to light emitted from.

The moving unit moves the cured object (d) in the first direction (D ₁ ), and emits light from the first ultraviolet ray LED array 110 and the second ultraviolet ray LED array 120 while the cured object (d) moves. may be exposed to exposed light. Alternatively, after the moving part fixes the cured object (d) at a position corresponding to the first ultraviolet LED array 110 and the second ultraviolet LED array 120, the first ultraviolet LED array 110 and the second ultraviolet LED array 120 2 It can be exposed to light emitted from the ultraviolet LED array 120. At this time, the moving unit may move the object to be cured (d) along the rail 400 extending in the first direction (D ₁ ).

Here, the cured body (d) may be extended in the first direction (D ₁ ). For this reason, the moving unit moves the cured object (d) in the first direction (D ₁ ), so that the ultraviolet curing device 100 of the present invention irradiates light in a manner specialized for the shape of the cured object (d). The object to be cured (d) can be cured efficiently.

Additionally, before the moving unit moves the cured object (d) in the first direction (D ₁ ), the cured object (d) is passed through the vision unit 310 and the alignment unit 320 of the alignment device 300. ) can be sorted. That is, after aligning the cured object (d) through the alignment device 300, the moving unit may move the cured object (d) in the first direction (D ₁ ). For example, the alignment mark 311 or the polarizing film 312 of the substrate supporting the cured object (d) is photographed through the vision portion 310, and the alignment mark photographed through the alignment portion 320 The substrate can be rotated using (311) or a polarizing film (312). For this reason, the ultraviolet curing device 100 of the present invention can effectively cure the cured object d by matching the irradiation position of the emitted light with the cured object d.

Figure 5 is a perspective view showing an ultraviolet curing device 100 according to an embodiment of the invention.

Looking at FIG. 5, it can be seen that the cured object d is exposed to light emitted from the first ultraviolet LED array 110 and the second ultraviolet LED array 120 while moving. At this time, it can be confirmed that the cured body (d) moves in the first direction (D ₁ ). In addition, it can be seen that the ultraviolet curing device 100 extends in the first direction (D ₁ ).

Figure 6 is a perspective view showing a banding protection layer forming system according to another embodiment of the present invention.

Referring to FIG. 6, the banding protection layer forming system according to another embodiment of the present invention will be examined in more detail. Matters that overlap with the parts described above in relation to the ultraviolet curing device 100 according to an embodiment of the present invention are Please omit it.

The banding protection layer forming system according to another embodiment of the present invention provides a movement path for the display panel (p) and aligns the display panel (p) with respect to the rail 400 extending in the first direction (D ₁ ). Alignment device 300; An application device 200 for partially applying the dispenser liquid for a banding protection layer (d) to one surface of the display panel (p) moving along the rail 400; And an ultraviolet curing device 100 according to an embodiment of the present invention that irradiates light to the dispenser liquid (d) for the banding protection layer applied to the display panel (p) moving along the rail 400. You can.

The alignment device 300 provides a movement path for the display panel p and can align the display panel p with the rail 400 extending in the first direction D ₁ . That is, after aligning the display panel using the alignment device 300, the dispenser liquid (d) for the banding protection layer can be applied and cured by moving it along a rail extending in the first direction. Due to this, the alignment device 300 can match the position at which the dispenser solution for a banding protection layer (d) is applied to the display panel (p) and the position at which light is irradiated to the applied dispenser solution for a banding protection layer (d). there is. Accordingly, the application position of the banding protective layer dispenser liquid (d) corresponds to the light irradiation position for the applied banding protective layer dispenser liquid (d), making it possible to effectively form a banding protective layer.

Here, the alignment device 300 rotates the display panel (p) using the vision unit 310 to photograph the alignment mark 311 of the display panel (p) and the photographed alignment mark 311. It may include unit 320. At this time, the alignment device 300 can align the display panel (p) based on the polarizing film 312 provided on the display panel (p). That is, the alignment device 300 can align the display panel p based on the pole line, which is the border of the polarizing film 312. Here, the dispenser liquid (d) for the banding protective layer may be applied without overlapping the polarizing film 312. The display panel (p) aligned through the alignment device 300 may move along the rail 400 extending in the first direction D ₁ through the moving unit.

The applicator 200 may partially apply the dispenser liquid (d) for a banding protection layer to one surface of the display panel (p) moving along the rail 400. That is, the application device 200 can apply the dispenser liquid (d) for a banding protection layer to one surface of the display panel (p) moving in the first direction (D ₁ ). For this reason, the dispenser liquid (d) for a banding protection layer applied to one surface of the display panel (p) may be extended in the first direction (D ₁ ).

The ultraviolet curing device 100 may irradiate light to the dispenser liquid (d) for the banding protection layer applied to the display panel (p) moving along the rail 400. That is, the ultraviolet curing device 100 can irradiate light to the dispenser liquid (d) for a banding protection layer applied to one surface of the display panel (p) moving in the first direction (D ₁ ). For this reason, the ultraviolet curing device 100 irradiates light in a specialized form for the form of the dispenser solution (d) for the banding protection layer applied while extending in the first direction (D ₁ ), thereby efficiently applying the dispenser solution for the banding protection layer. (d) can be hardened.

The banding protection layer forming system of the present invention may be a facility for forming a coating layer to protect the display panel (p) from the moisture permeability of fine cracks that may occur during bending of the display panel (p). there is. For this reason, the dispenser liquid (d) for the banding protection layer may be extended in one direction.

Figure 7 is a flowchart showing an ultraviolet curing method according to another embodiment of the present invention.

Referring to FIG. 7, the ultraviolet curing method according to another embodiment of the present invention will be examined in more detail. The ultraviolet curing device 100 according to one embodiment of the present invention and the banding protection layer formation according to another embodiment of the present invention. Regarding the system, items that overlap with those previously explained should be omitted.

An ultraviolet curing method according to another embodiment of the present invention includes a process (S100) in which a moving part moves the object to be cured (d) in the first direction (D ₁ ); and a first ultraviolet LED array 110 including a plurality of first ultraviolet LEDs 111 arranged in a row in the first direction (D ₁ ) and a plurality of second ultraviolet LED arrays 110 arranged in a row in the first direction (D ₁ ). A process (S200) in which the ultraviolet curing device 100, which provides a second ultraviolet LED array 120 including ultraviolet LEDs 121, irradiates light to the object to be cured (d) (S200), wherein the first ultraviolet rays The peak wavelength of the light emitted from the LED 111 may be longer than the peak wavelength of the light emitted from the second ultraviolet LED 121.

First, the moving unit moves the cured object (d) in the first direction (D ₁ ) (S100). The moving unit moves the cured object (d) in the first direction (D ₁ ), and emits light from the first ultraviolet ray LED array 110 and the second ultraviolet ray LED array 120 while the cured object (d) moves. may be exposed to exposed light. Alternatively, after the moving part fixes the cured object (d) at a position corresponding to the first ultraviolet LED array 110 and the second ultraviolet LED array 120, the first ultraviolet LED array 110 and the second ultraviolet LED array 120 2 It can be exposed to light emitted from the ultraviolet LED array 120.

Here, before the moving unit moves the cured object (d) in the first direction (D ₁ ), the cured object (d) may be aligned through the vision unit 310 and the alignment unit 320. For example, by photographing the alignment mark 311 of the substrate supporting the object to be cured (d) through the vision unit 310, and using the alignment mark 311 photographed through the alignment unit 320, The substrate can be rotated.

Next, a first ultraviolet LED array 110 including a plurality of first ultraviolet LEDs 111 arranged in a row in the first direction (D ₁ ) and a plurality of first ultraviolet LED arrays 110 arranged in a row in the first direction (D ₁ ). An ultraviolet curing device 100 that provides a second ultraviolet LED array 120 including second ultraviolet LEDs 121 irradiates light to the object to be cured (d) (S200). At this time, each of the first ultraviolet LED array 110 and the second ultraviolet LED array 120 forms a plurality of rows, thereby increasing the amount of emitted light.

Here, the peak wavelength of the light emitted from the first ultraviolet LED 111 may be longer than the peak wavelength of the light emitted from the second ultraviolet LED 121. That is, the ultraviolet curing device 100 of the present invention may be provided with a plurality of ultraviolet LEDs having different peak wavelengths. For example, the peak wavelength of light emitted from the first ultraviolet LED 111 may be 360 nm, and the peak wavelength of light emitted from the second ultraviolet LED 121 may be 310 nm. For this reason, the peak wavelength of the light emitted from the first ultraviolet LED 111 penetrates deep into the interior of the object to be cured (d) due to its long wavelength, thereby allowing the interior of the object to be cured (d) to be cured. In addition, the peak wavelength of the light emitted from the second ultraviolet LED 121 has a short wavelength, so the surface of the cured object d can be cured and the coated state of the cured object d can be maintained without deformation. Accordingly, the ultraviolet curing device 100 of the present invention can effectively cure the surface and interior of the object to be cured (d).

The first ultraviolet LED array 110 is provided in plural numbers on both sides of the second ultraviolet LED array 120 and may be symmetrical to each other.

The first ultraviolet LED array 110 is provided in plurality on both sides around the second ultraviolet LED array 120 and is symmetrical to each other, so that light can be uniformly irradiated to the object to be cured d. Here, the peak wavelength of the light emitted from the first ultraviolet LED 111 and the peak wavelength of the light emitted from the second ultraviolet LED 121 may be different from each other. For this reason, the ultraviolet curing device 100 is better when the first ultraviolet LED array 110 is provided on both sides around the second ultraviolet LED array 120 than when the plurality of ultraviolet LED arrays 110 are not provided on both sides. More uniform light can be emitted. For example, when the object to be cured (d) is extended in the first direction (D ₁ ), the light emitted from the first ultraviolet LED array 110 is uniformly irradiated to the object to be cured (d) on both sides. Thus, the object to be cured (d) can be cured efficiently.

The amount of light emitted from the first ultraviolet LED array 110 may be greater than the amount of light emitted from the second ultraviolet LED array 120.

Since the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, when light is irradiated to the object to be cured (d), the surface of the object to be cured (d) and The interior can be hardened evenly. Here, the first ultraviolet LED 111 of the first ultraviolet LED array 110 cures the inside of the object to be cured (d), and the second ultraviolet LED 121 of the second ultraviolet LED array 120 cures the inside of the object to be cured (d). The surface of the cured body (d) can be hardened. When curing the object (d), the interior has a larger volume than the surface, so more energy and time may be needed to cure the interior than the surface of the object (d). At this time, in the ultraviolet curing device 100 of the present invention, the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, so that the cured object (d) When irradiated with light, the inside of the object to be cured (d) can be sufficiently cured. For this reason, the ultraviolet curing device 100 of the present invention can uniformly and efficiently cure the surface and interior of the object to be cured (d).

The peak wavelength of the light emitted from the first ultraviolet LED 111 may be 355 to 385 nm, and the peak wavelength of the light emitted from the second ultraviolet LED 121 may be 300 to 330 nm.

Since the peak wavelength of the light emitted from the first ultraviolet LED 111 is 355 to 385 nm, when light is irradiated to the object to be cured (d), it penetrates deep into the interior of the object to be cured (d) due to the long wavelength. ) can harden the interior. For example, the peak wavelength of light emitted from the first ultraviolet LED 111 may be 365 nm.

Since the peak wavelength of the light emitted from the second ultraviolet LED 121 is 300 to 330 nm, the surface of the cured object (d) is cured due to the short wavelength when light is irradiated to the cured object (d) without deformation ( The application state of d) can be maintained. For example, the peak wavelength of light emitted from the second ultraviolet LED 121 may be 310 nm.

In this way, the ultraviolet curing device 100 of the present invention has a peak wavelength of light emitted from the first ultraviolet LED 111 of 355 to 385 nm and a peak wavelength of light emitted from the second ultraviolet LED 121 of 300 to 330 nm. As a result, the surface and interior of the object to be cured (d) can be effectively cured. In particular, since the amount of light emitted from the first ultraviolet LED array 110 is greater than the amount of light emitted from the second ultraviolet LED array 120, when light is irradiated to the object to be cured (d), The surface and interior can be hardened uniformly. At this time, the object to be cured (d) may be an acrylic resin.

As such, in the present invention, the ultraviolet curing device includes a first ultraviolet light LED array having a plurality of first ultraviolet LEDs and a second ultraviolet light LED array having a plurality of second ultraviolet LEDs, and can replace a halogen lamp. In addition, by providing the first ultraviolet light LED and the second ultraviolet light LED, the object to be cured can be efficiently cured using a specific peak wavelength. At this time, the peak wavelength of the light emitted from the first ultraviolet LED is longer than the peak wavelength of the light emitted from the second ultraviolet LED, and the light emitted from the first ultraviolet LED penetrates deep into the interior of the object to be cured due to its long wavelength, curing the interior. You can do it. In addition, the light emitted from the second ultraviolet LED can harden the surface of the cured object due to its short wavelength and maintain the applied state of the cured object without deformation. That is, the ultraviolet curing device of the present invention can effectively cure the surface and interior of the object to be cured. Here, since the amount of light emitted from the first ultraviolet LED array is greater than the amount of light emitted from the second LED array, the surface and interior of the object to be cured can be cured uniformly. A plurality of first ultraviolet LED arrays are provided on both sides around the second ultraviolet LED array and are symmetrical to each other, so that uniform light can be irradiated to the object to be cured. In addition, the ultraviolet curing device of the present invention further includes an optical measurement unit including an optical fiber, a reflector, and an optical sensor, and can measure emitted light by ensuring stability by preventing deterioration due to high temperature. And the ultraviolet curing device of the present invention further includes a control unit, and can control the amount of light of at least one of each row of the first ultraviolet LED array and the second ultraviolet LED array using the illuminance of the light measured by the light measuring unit. . In addition, the ultraviolet curing device of the present invention further includes a cooling unit, and can ensure stability by cooling the heat caused by light emitted from the first ultraviolet LED and the second ultraviolet LED.

And the banding protective layer forming system includes an alignment device, an application device, and an ultraviolet curing device of the present invention, and after aligning the display panel, the display panel is moved along a rail extending in the first direction to apply and cure the dispenser liquid for the banding protective layer. You can. Due to this, the application position of the dispenser liquid for the banding protective layer corresponds to the light irradiation position for the applied dispenser liquid for the banding protective layer, making it possible to effectively form a banding protective layer. At this time, each of the first ultraviolet LED array and the second ultraviolet LED array of the ultraviolet curing device of the present invention has a shape extending in the first direction, so that light can be irradiated specifically to the banding protection layer.

In addition, the ultraviolet curing method involves irradiating light to the object to be cured through a first ultraviolet light LED array having a plurality of first ultraviolet LEDs and a second ultraviolet light LED array having a plurality of second ultraviolet LEDs, using a halogen lamp. can be replaced. In addition, since the peak wavelength of the light emitted from the first ultraviolet LED is different from the peak wavelength of the light emitted from the second ultraviolet LED, the surface and interior of the object to be cured can be effectively cured.

Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the above-described embodiments, and is within the scope of common knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Those who have will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the scope of technical protection of the present invention should be determined by the scope of the patent claims below.

D ₁ : First direction d: Dispenser liquid for cured material, banding protective layer
p: display panel 100: ultraviolet curing device
110: first ultraviolet LED array 111: first ultraviolet LED
120: Second ultraviolet LED array 121: Second ultraviolet LED
130: Lens-type light guide plate 140: Light measurement unit
141: optical fiber 142: reflector
143: optical sensor 150: support
160: cooling unit 161: heat sink
162: fan 200: applicator
300: Alignment device 310: Vision section
311: Alignment mark 312: Polarizing film
320: alignment part 400: rail

Claims (15)

a first ultraviolet LED array including a plurality of first ultraviolet LEDs arranged in a row in a first direction;
a second ultraviolet LED array including a plurality of second ultraviolet LEDs arranged in a row in the first direction; and
It includes a light measuring unit that measures the illuminance of light emitted from the first ultraviolet LED array or the second ultraviolet LED array,
The peak wavelength of the light emitted from the first ultraviolet LED is longer than the peak wavelength of the light emitted from the second ultraviolet LED,
The optical measurement unit is,
Optical fibers that form an optical path and allow light to pass through;
a reflector disposed at one end of the optical fiber to reflect light emitted from the first ultraviolet LED array or the second ultraviolet LED array to the optical fiber; and
An optical sensor disposed at the other end of the optical fiber and measuring the illuminance of light passing through the optical fiber. In claim 1,
An ultraviolet curing device in which a plurality of the first ultraviolet LED array is provided on both sides around the second ultraviolet LED array. In claim 1,
The first ultraviolet LED array is an ultraviolet curing device that is symmetrical with respect to the second ultraviolet LED array. In claim 1,
The amount of light emitted from the first ultraviolet LED array is greater than the amount of light emitted from the second ultraviolet LED array. In claim 1,
The peak wavelength of the light emitted from the first ultraviolet LED is 355 to 385 nm,
An ultraviolet curing device in which the peak wavelength of light emitted from the second ultraviolet LED is 300 to 330 nm. In claim 1,
An ultraviolet curing device further comprising a lens-type light guide plate that receives light emitted from the first ultraviolet LED array and the second ultraviolet LED array and provides mixed light thereof to the object to be cured. delete In claim 1,
An ultraviolet curing device further comprising a control unit that controls the amount of light in at least one of each row of the first ultraviolet LED array and the second ultraviolet LED array, using the illuminance of the light measured by the light measurement unit. In claim 1,
a support portion provided on one side of the first ultraviolet LED array and the second ultraviolet LED array to support the first ultraviolet LED array and the second ultraviolet LED array; and
It further includes a cooling unit provided on the other side of the support unit to cool the heat generated from the first ultraviolet LED and the second ultraviolet LED,
An ultraviolet curing device in which the optical fiber of the light measuring unit penetrates the support part. In claim 1,
It further includes a moving part that moves the cured body in the first direction,
An ultraviolet curing device in which the cured object is exposed to light emitted from the first ultraviolet LED array and the second ultraviolet LED array while moving. an alignment device that provides a movement path for the display panel and aligns the display panel with respect to a rail extending in a first direction;
an applicator for partially applying a dispenser liquid for a banding protection layer to one surface of the display panel moving along the rail; and
A banding protection layer forming system comprising: an ultraviolet curing device according to any one of claims 1 to 6 or claims 8 to 10, which irradiates light to the dispenser liquid for the banding protection layer applied to the display panel moving along the rail; . an alignment device that provides a movement path for the display panel and aligns the display panel with respect to a rail extending in a first direction;
an applicator for partially applying a dispenser liquid for a banding protection layer to one surface of the display panel moving along the rail; and
It includes an ultraviolet curing device that irradiates light to the dispenser liquid for the banding protection layer applied to the display panel moving along the rail,
The ultraviolet curing device,
a first ultraviolet LED array including a plurality of first ultraviolet LEDs arranged in a row in a first direction; and
It includes; a second ultraviolet LED array including a plurality of second ultraviolet LEDs arranged in a row in the first direction;
A banding protection layer forming system wherein the peak wavelength of the light emitted from the first ultraviolet LED is longer than the peak wavelength of the light emitted from the second ultraviolet LED. A process in which the moving unit moves the cured object in a first direction;
UV curing that provides a first ultraviolet LED array having a plurality of first ultraviolet LEDs arranged in a row in the first direction and a second ultraviolet LED array having a plurality of second ultraviolet LEDs arranged in a row in the first direction. A process in which a device irradiates light to the object to be cured; and
A process of measuring the illuminance of the light with a light measurement unit,
The peak wavelength of the light emitted from the first ultraviolet LED is longer than the peak wavelength of the light emitted from the second ultraviolet LED,
The optical measurement unit is,
Optical fibers that form an optical path and allow light to pass through;
a reflector disposed at one end of the optical fiber to reflect light emitted from the first ultraviolet LED array or the second ultraviolet LED array to the optical fiber; and
An optical sensor disposed at the other end of the optical fiber and measuring the illuminance of light passing through the optical fiber. In claim 13,
An ultraviolet curing method in which a plurality of the first ultraviolet LED arrays are provided on both sides of the second ultraviolet LED array and are symmetrical to each other. In claim 13,
The amount of light emitted from the first ultraviolet LED array is greater than the amount of light emitted from the second ultraviolet LED array.

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