KR102282910B1 - Light Guide Unit And Transmission Type Flat Panel Illumination Device Having It - Google Patents

Abstract

The present invention relates to a light guide unit having a double pattern and a transmissive flat light having the same, wherein the flat light having a transmissive characteristic minimizes light reflection to the upper surface to prevent glare, and directs the light to the lower surface to illuminate the subject. A light guide unit having a double pattern for improving sharpness in an observation box, and a transmissive flat panel lighting device having the same.

Description

Light Guide Unit And Transmission Type Flat Panel Illumination Device Having It}

The present invention relates to a light guide unit having a double pattern and a transmissive flat light having the same, wherein the flat light having a transmissive characteristic minimizes light reflection to the upper surface to prevent glare, and directs the light to the lower surface to illuminate the subject. A light guide unit having a double pattern for improving sharpness in an observation box, and a transmissive flat panel lighting device having the same.

In a method of inspecting goods such as semiconductors and circuit boards, LED lighting devices have been used to inspect defects that may affect the quality of products, such as defects, scratches, and foreign substances.

The conventional LED lighting apparatus uses a method of observing a subject by photographing and observing it through a CCD camera using the LED lighting or inspecting it with the naked eye of an inspector when observing a subject.

However, the conventional LED lighting device has a problem in that it is difficult to guarantee the inspection result and the visual observation result because the light source is not evenly distributed over the entire area of the subject.

Therefore, research and development of a transmissive flat panel lighting device capable of ensuring good quality results by illuminating a subject with an even light source positioned on the same line as the LED light source with the gaze of the observation camera and the observer is being researched and developed.

However, the conventional transmissive flat panel lighting device is configured to include a light guide plate that transmits light emitted from the light source on the side downward, but a fine pattern is applied to the light guide plate to reflect the light emitted from the light source on the side to the maximum and transmit it downward. However, since the thickness of the light guide plate for use in a transmissive flat panel lighting device is thick, pattern processing is difficult, and accordingly, there is a problem of low transmittance.

The purpose of the present invention is to improve the structure of the light guide plate so that the light of the illumination illuminates the lower surface as much as possible to facilitate the examination of the subject, and the light source of the electronic light source unit is the eye of the examiner. An object of the present invention is to provide a light guide unit having a double pattern that can be transmitted minimally and a transmissive flat light having the same.

In order to achieve the above object, a light guiding unit according to the present invention is a light guiding unit for a transmissive flat panel lighting device that guides light emitted from a light source unit downward; a light guide member for reflecting light emitted from the light source, scattered and incident downward; a light guide plate having an embossed pattern formed thereon; an optical adhesive layer for bonding the light guide and the light guide plate in an integral shape; including an embossed pattern on an upper surface of the light guide plate; It is characterized in that it has a double pattern structure in which an engraved pattern corresponding to the embossed pattern is formed on an optical adhesive layer coupled to the upper surface of the light guide plate on which the embossed pattern is formed.

Here, the light guide unit, characterized in that it further comprises a reflective member for reflecting the light emitted from the light source disposed on the side to the upper portion of the light guide member downward.

The optical adhesive layer is composed of an OCA optical silicone pad, and the embossed pattern formed on the upper surface of the lower light guide plate serves as a mold, and an intaglio pattern is formed on the lower surface of the OCA optical adhesive layer when compressed. of the optical guide member and the lower light guide plate in an integral shape, and an intaglio pattern that engages with the embossed pattern of the light guide plate reflects the light emitted from the light source on the side slope to the lower surface. It is characterized in that the transmittance can be increased by refracting the light downward.

When the optical adhesive layer is a viscous material and is pressed against the light guide plate at the bottom, the embossed pattern of the light guide plate is transferred to the optical adhesive layer, and an intaglio pattern corresponding to the embossed pattern of the light guide plate is formed on the optical adhesive layer to form a double pattern. ; If the optical adhesive layer and the light guide plate are not completely in close contact, but only the flat portion of the light guide plate is pressed into close contact with the optical adhesive layer and cured by removing the compression, the intaglio pattern is transferred to the optical adhesive layer during the time during which the optical adhesive layer and the light guide plate are compressed, When the compression is removed, the optical adhesive layer is slightly spaced apart from the light guide plate by restoring force, and the inclined surfaces of the embossed pattern and the engraved pattern do not completely contact each other, thereby forming a double pattern structure.

On the other hand, the transmissive flat panel lighting device according to the present invention is formed on both sides of the light source unit for emitting light; the above-described light guide unit formed between the light source units to guide the light emitted from the light source unit downward; an upper cover coupled to the upper portion of the light guide unit and having an open center; It is characterized in that it has a frame structure coupled to the lower portion of the light guide unit and includes a lower cover with an open center.

The light source unit includes heat dissipation frames formed on both sides; a light source mounted in the heat dissipation frame; a heat dissipation pad attached between the heat dissipation frame and the light source, and the heat generated by the light source is cooled by natural convection through the heat dissipation pad and the heat dissipation fins of the heat dissipation frame; The light sources are arranged on four sides, but are arranged at regular intervals so as not to generate shadows so that light can be transmitted to the center of the light guide plate, and are spaced apart from the light guide unit by a certain distance to prevent light scattering and to increase linear transmission efficiency. characterized in that it is composed.

The light source unit has a structure in which power is applied to the light source and heat generated while light is emitted is transferred to the heat dissipation pad to dissipate heat in the heat dissipation frame, and the upper cover and the lower cover with an open center are bound to the heat dissipation frame to induce air flow, , heat dissipation is a natural convection structure, and it is characterized in that it is leaked to the outside through an air hole perforated in the cover with an open top, so that it is possible to remove the cause of malfunction or failure due to the heat generated by the light source.

The light source is disposed at an eccentric position downward so that light is directly irradiated to the double pattern between the optical adhesive layer and the light guide plate, rather than the center, so that it is possible to increase the effect of transmitting the light to the bottom.

As described above, in the light guiding unit and the transmissive flat panel lighting device having the same according to the present invention, the light of illumination illuminates the lower surface as much as possible to facilitate inspection of the subject with the naked eye, including the inspection method using a camera, and the eyes of the inspector As a result, an excellent effect occurs so that the light source of the electronic light source can be transmitted to the minimum.

In particular, the present invention is a lighting for improving the presence of glare due to light blur or light reflection when observing a subject located on the lower surface from the upper surface using illumination. By refracting the side light source to the lower surface as much as possible to the upper surface When only a minimum amount of light is transmitted, when observing a subject with a reflective characteristic located below, an excellent effect of observing without glare occurs even with the light of the observer's gaze.

1 schematically shows a method for inspecting a subject using a projection-type flat panel lighting device according to a preferred embodiment of the present invention;
2 schematically shows a transmissive flat panel lighting device according to a preferred embodiment of the present invention;
3 schematically illustrates a process in which light emitted from a light source is transmitted downward according to a preferred embodiment of the present invention.
4 is a cross-sectional view schematically illustrating a transmissive flat panel lighting device according to a preferred embodiment of the present invention.

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

1 schematically shows a method for inspecting a subject using a transmissive flat panel lighting device according to a preferred embodiment of the present invention, and FIG. 2 schematically shows a transmissive flat panel lighting device according to a preferred embodiment of the present invention. 3 schematically illustrates a process in which light emitted from a light source is transmitted downward according to a preferred embodiment of the present invention.

Referring to FIG. 1 , in the transmissive flat panel lighting device 10 according to the present invention, the upper part is opened and the lower part is also opened so that the subject 30 can be observed well through the gaze of the examiner 20, so that the subject 30 located in the lower part is opened. ) can be seen.

Referring to FIG. 2 , the transmissive flat panel lighting device 10 is formed between a light source unit 110 , which is formed on both sides and emits light, and the light source unit to guide the light emitted from the light source unit downward. The unit 120 and the upper cover 130 coupled to the upper part of the light guiding unit and having an open center, and the lower cover 140 coupled to the lower part of the light guiding unit and having an open center may be configured as a combined frame structure. .

The light source unit 110 may include heat dissipation frames formed on both sides, a light source 111 mounted in the heat dissipation frame, and a heat dissipation pad 113 attached between the heat dissipation frame 112 and the light source. Here, the heat generated by the light source 111 may be cooled by naturally convecting through the heat dissipation fins of the heat dissipation pad 113 and the heat dissipation frame 112 .

The light source 111 may be configured in a form in which an LED is mounted on a circuit board, and arranged on four sides, but arranged at intervals of 4 to 5 mm so as not to cause a shadow, so that light can be transmitted to the center of the light guide plate. In addition, when the light guide unit 120 is in direct contact with the light guiding unit 120, since light loss occurs due to scattered light, it may be spaced apart by a predetermined distance to prevent light scattering and to increase linear transmission efficiency.

4 is a cross-sectional view schematically illustrating a transmissive flat panel lighting device according to a preferred embodiment of the present invention.

4, the light source unit 110 is provided with a heat dissipation frame 112 and may be formed in a structure in which four sides are assembled through extrusion, and may be assembled including a heat conducting member to increase the heat conduction effect. , The heat dissipation frame 112 may be composed of a horizontal fin type extruded material to maximize heat conduction and transmission, and air holes are provided on the four edges of the upper surface of the upper cover to increase heat dissipation efficiency by accelerating the flow of air. This can be configured.

Accordingly, the light source 111 has a structure in which the heat generated while power is applied and light is emitted is transferred to the heat dissipation pad 113 to dissipate heat in the heat dissipation frame 112, and the upper cover 130 and the lower cover 130 with the center open 140) is bound to the heat dissipation frame 112 to induce air flow, and the heat dissipates to the outside through the air hole 131 perforated in the cover with an open top in a natural convection structure, resulting in heat generated from the light source. The cause of malfunction or failure can be eliminated.

The light source unit 110 has a structure corresponding to the light guide unit 120 , and has a structure in which a light source is disposed adjacent to the light guide unit 120 so that light emitted from the light source is reflected at a right angle. Here, the light source may be composed of a point light source LED.

The light guide unit 120 may be formed in a stacked structure, and includes a light guide member 121 that reflects light emitted from the light source, scattered and incident downward, a light guide plate 122 having an embossed pattern formed thereon, and the light guide; It may be configured to include an optical adhesive layer 123 for bonding the light guide plate in an integral shape.

Here, the upper portion of the light guide member 121 may further include a reflective member 124 for reflecting the light emitted from the light source disposed on the side downward.

Here, the light guide member 121 is composed of a transparent film in the form of a flat film, and has a thickness of 5 mm, and serves to reflect the light emitted from the scattered and incident light source downward.

And the light guide plate 122 includes an embossed pattern formed on the upper surface.

Here, referring to FIG. 3, the light guide unit has a structure in which power is applied to the light source and heat generated while light is emitted is transferred to the heat dissipation pad to dissipate heat from the heat dissipation plate, and the upper cover and the lower cover with an open center are attached to the heat dissipation frame. to induce air flow.

Accordingly, heat radiation is discharged to the outside through an air hole perforated in the cover having an open top in a natural convection structure, so that it is possible to remove the cause of malfunction or failure due to the heat generated by the light source.

The light source unit 110 has a structure corresponding to the light guide unit 120 , and has a structure in which a light source is disposed adjacent to the light guide unit 120 so that light emitted from the light source is reflected at a right angle. Here, the light source may be composed of a point light source LED.

The light guide unit 120 may be formed in a stacked structure, and includes a light guide member 121 that reflects light emitted from the light source, scattered and incident downward, a light guide plate 122 having an embossed pattern formed thereon, and the light guide; It may be configured to include an optical adhesive layer 123 for bonding the light guide plate in an integral shape.

Here, the upper portion of the light guide member 121 may further include a reflective member 124 for reflecting the light emitted from the light source disposed on the side downward.

The reflective member 124 may be configured as a separate transparent reflective film to be laminated with the optical guide member, and may include a reflective coating layer coated on the upper surface of the optical guide member.

The light guide member 121 is composed of a transparent film in the form of a flat film, and has a thickness of 5 mm, and serves to reflect the light emitted from the scattered and incident light source downward.

And the light guide plate 122 includes an embossed pattern formed on the upper surface.

Here, when the light guide unit 120 is composed of a single layer of the light guide member, the scattered light incident therein is not reflected down but is emitted to the upper portion, and there is a problem in that the transmittance to the lower portion is low. The light guide member is formed in a structure in which the light guide member and the light guide plate are laminated to reflect the light downward, and a pattern is formed on the upper surface of the light guide plate corresponding to the inner interface between the light guide member and the light guide plate, and the light is transmitted through total reflection through the pattern. can be reflected by

When the pattern 122a formed on the upper surface of the light guide plate 122 is engraved, it is advantageous to totally reflect the light introduced into the light guide plate downward, so that the transmittance to the lower portion can be increased, but the thickness of the light guide plate is limited. Due to this, there is a problem in that it is difficult to form a pattern with an intaglio.

Accordingly, an embossed pattern 122a for easy processing is formed on the upper surface of the light guide plate, and an intaglio pattern 123a corresponding to the embossed pattern is formed on the optical adhesive layer 123 coupled to the upper surface of the light guide plate on which the embossed pattern is formed. As in the case where an intaglio pattern is formed on the light guide plate, the transmittance to the lower portion may be increased.

The embossed pattern 122a of the light guide plate may have a cross-section in a shape capable of total reflection, such as a prism or a trapezoid, and it is preferable that the number of embossed patterns does not exceed 7 million in order to increase the transmittance, and the embossed pattern is engaged with the embossed pattern 122a. The engraved pattern 123a of the optical adhesive layer has a double pattern of a structure in which the shape of a point or a line is not visible when viewed by an observer.

The optical adhesive layer 123 may be composed of an OCA optical silicon pad of 0.1 mm, and the embossed pattern formed on the upper surface of the lower light guide plate serves as a mold, and an engraved pattern 123a is formed on the lower surface of the OCA optical adhesive layer when compressed.

Accordingly, the optical adhesive layer 123 serves to protect the embossed pattern 122a of the light guide plate in contact with the lower portion, and bonds the upper optical guide member 121 and the lower light guide plate 122 in an integral shape, and The engraved pattern 123a engaged with the embossed pattern 122a has a double pattern structure in which the light emitted from the light source of the side slope is reflected to the lower surface, and the transmittance can be increased by guiding the light of the light source to the lower surface.

When the light guide member is composed of a single layer, there is a problem in that the scattered light incident inside is not reflected down but is emitted to the upper side, and there is a problem that the transmittance to the lower side is low. The guide member is formed in a structure in which the guide member is laminated with the lower light guide plate, and a pattern is formed on the upper surface of the light guide plate corresponding to the inner interface between the light guide member and the light guide plate to reflect light downward through total reflection through the pattern.

When the pattern formed on the upper surface of the light guide plate is formed in an intaglio, it is advantageous to totally reflect the light introduced into the light guide plate downward, so that the transmittance to the lower part can be increased. However, due to the limitation of the thin thickness of the light guide plate, the pattern is formed in an intaglio There is a problem that is difficult to do.

Therefore, an embossed pattern that is easy to process is formed on the upper surface of the light guide plate, and an engraved pattern corresponding to the embossed pattern is formed on the optical adhesive layer coupled to the upper surface of the light guide plate on which the embossed pattern is formed, so that the engraved pattern is formed on the light guide plate Likewise, it is possible to increase the transmittance to the lower part.

The embossed pattern 122a of the light guide plate may have a cross-section in a shape capable of total reflection, such as a prism or a trapezoid, and it is preferable that the number of embossed patterns does not exceed 7 million in order to increase the transmittance, and the embossed pattern is engaged with the embossed pattern 122a. The engraved pattern of the optical adhesive layer has a double pattern of a structure in which the shape of a point or a line is not visible when viewed by an observer.

The optical adhesive layer 123 may be composed of an OCA optical silicon pad of 0.1 mm, and the embossed pattern formed on the upper surface of the lower light guide plate serves as a mold, and an engraved pattern 123a is formed on the lower surface of the OCA optical adhesive layer when compressed.

Here, the optical adhesive layer 123 has a thickness of less than 0.1 mm, and the height of the pattern formed on the light guide plate should not exceed 0.02 mm, and the area should not exceed 0.04 pie, so that the pattern line or transmittance to the observer's eye is not less than 80%. It is desirable to design it so that

When the optical adhesive layer 123 is a viscous material and is pressed against the light guide plate below, the embossed pattern 122a of the light guide plate is transferred to the optical adhesive layer, and the optical adhesive layer has an engraved pattern 123a corresponding to the embossed pattern of the light guide plate. This is formed to form a double pattern.

Here, if the optical adhesive layer 123 and the light guide plate 122 are bonded together with excessively high pressure and time, the upper surface of the light guide plate comes into complete contact with the optical adhesive layer, and in this case, the reflection effect by the pattern may be reduced.

Therefore, if the optical adhesive layer and the light guide plate are not completely adhered to each other and only the flat portion of the light guide plate is bonded and cured to the extent that it is in close contact with the optical adhesive layer, the inclined surface of the pattern is not completely bonded and the spaced state is maintained. The transmittance can be increased by maximizing the phenomenon that the light of the slope is refracted to the lower surface.

The optical adhesive layer 123 and the light guide plate 122 are instantaneously compressed for 1 to 2 seconds for the time of applying the compression, and then when the compression is removed, the engraved pattern is transferred to the optical adhesive layer during the time during which the optical adhesive layer and the light guide plate are compressed, and the compression is removed. As the optical adhesive layer is slightly spaced apart from the light guide plate by the restoring force, the inclined surfaces of the embossed pattern 122a and the engraved pattern 123a do not completely contact each other, thereby forming a double pattern as shown in FIG. 5 .

Accordingly, the optical adhesive layer 123 serves to protect the embossed pattern 122a of the light guide plate in contact with the lower portion, and bonds the upper optical guide member and the lower light guide plate in an integral shape, and engages the embossed pattern of the light guide plate. The engraved pattern 123a has a double pattern structure that reflects light emitted from the light source on the side slope to the lower surface, so that the light from the light source is guided to the lower surface to increase transmittance.

6 schematically shows a path of emitted light through a light guide unit according to a preferred embodiment of the present invention.

Referring to FIG. 6, in the present invention, the light emitted by the light source is refracted downward by the double pattern between the light guide plate and the optical adhesive layer, and the light propagating upward is applied to the reflective member disposed on the upper part of the light guide member. Since it is a downwardly refracting structure, it is possible to maximize transmission to the lower surface of the object while minimizing interference with the observer's field of view and inspection of the correct shape of the object in the lens of the camera.

Here, the light source of the light source unit is disposed at an eccentric position so that light is directly irradiated to the double pattern between the optical adhesive layer and the light guide plate, rather than the center, so that the effect of penetrating downward can be enhanced.

10: transmissive flat panel lighting device 20: observer
30: subject

Claims (8)

A light guiding unit for a transmissive flat panel lighting device for visually inspecting a subject by guiding light emitted from the light source unit downward;
a light guide member for reflecting the light emitted from the light source, scattered and incident downward; a light guide plate having an embossed pattern formed thereon; an optical adhesive layer for bonding the light guide and the light guide plate in an integral shape;
The optical adhesive layer is
When the viscous material is pressed to the lower light guide plate, the embossed pattern of the light guide plate is transferred to the optical adhesive layer, and an engraved pattern corresponding to the embossed pattern of the light guide plate is formed on the optical adhesive layer to form a double pattern;
The optical adhesive layer is composed of an O CA optical silicon pad, and the embossed pattern formed on the upper surface of the lower light guide plate serves as a template, and an intaglio pattern is formed on the lower surface of the OCA optical adhesive layer when compressed. The upper optical guide member and the lower light guide plate are joined together in an integral shape, and the intaglio pattern that engages the embossed pattern of the light guide plate reflects the light emitted from the light source on the side slope to the lower surface. The transmitted light can be refracted downward to increase the transmittance;
If the optical adhesive layer and the light guide plate are not completely in close contact, and only the flat portion of the light guide plate is pressed into close contact with the optical adhesive layer and cured by removing the compression, the intaglio pattern is transferred to the optical adhesive layer during the time during which the optical adhesive layer and the light guide plate are compressed, When the compression is removed, the optical adhesive layer is slightly spaced apart from the light guide plate by the restoring force, and the inclined surfaces of the embossed pattern and the intaglio pattern do not completely contact, and a double pattern structure is formed, as if the intaglio pattern is formed on the light guide plate. The light guide unit, characterized in that it can increase the transmittance of the.
The method of claim 1,
The light guide unit according to claim 1, further comprising a reflective member on the upper portion of the light guide member for reflecting light emitted from a light source disposed on a side thereof downward.
delete delete a light source unit formed on both sides to emit light;
a light guide unit formed between the light source units and configured to guide the light emitted from the light source unit downward;
an upper cover coupled to the upper portion of the light guide unit and having an open center;
A transmissive flat panel lighting device coupled to a lower portion of the light guide unit and configured to include a frame structure coupled including a lower cover with an open center to inspect a subject with the naked eye.
6. The method of claim 5,
The light source unit
a heat dissipation frame formed on both sides;
a light source mounted in the heat dissipation frame;
a heat dissipation pad attached between the heat dissipation frame and the light source, and the heat generated by the light source is naturally convected and cooled through the heat dissipation pad and the heat dissipation fins of the heat dissipation frame;
The light sources are arranged on four sides, but are arranged at regular intervals so as not to generate shadows so that light can be transmitted to the center of the light guide plate, and are spaced apart from the light guide unit by a certain distance to prevent light scattering and to increase linear transmission efficiency. Transmissive flat panel lighting device, characterized in that it is configured.
7. The method of claim 6,
The light source unit
It has a structure in which the heat generated while power is applied to the light source is transferred to the heat dissipation pad to dissipate heat in the heat dissipation frame, and the upper and lower covers with an open center are bound to the heat dissipation frame to induce air flow, and heat dissipation is natural. Transmissive flat panel lighting device, characterized in that it is leaked to the outside through the air hole perforated in the cover with the upper part open in a convection structure, so that it is possible to remove the cause of malfunction or failure due to the heat generated by the light source.
7. The method of claim 6,
The light source is
A transmissive flat panel lighting device, characterized in that it is disposed at an eccentric downward position so that light is directly irradiated to the double pattern between the optical adhesive layer and the light guide plate, rather than the center, so that the downward transmission effect can be enhanced.

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