KR20190111731A - A Reflection Type Surface Emitting Lighting - Google Patents

Abstract

The present invention relates to surface emission illumination, which performs surface emission on a wide area with a light emitting diode (LED) having point emission. A lighting device of the present invention comprises: a reflective member (10) arranged at a predetermined angle (a) of 0° or more with respect to an emission surface (20), which is surface-emitted; and a light source (30) for irradiating light toward the reflective member (10) between the emission surface and a reflective profile surface (13) of the reflective member (10). The reflective member (10) includes: a film member (11) having a first surface having the reflective profile surface (13) and a second surface opposite to the first surface; and first and second reflective surfaces (14, 15) alternately provided on a surface of the reflective profile surface (13) in a longitudinal direction of the film member. Incident light (61) emitted from a light source (30) is incident on the first reflective surface (14). A first reflective light (62) in which the incident light (61) is reflected by the first reflective surface (14), is incident on the second reflective surface (15) which is adjacent to the first reflective surface (14) and is arranged to be closer to the light source (30) than the first reflective surface (14). Also, a second reflective light (63) in which the first reflective light (62) is reflected by the second reflective surface (15), intersects the incident light (61) and is emitted toward the emission surface (20).

Description

Reflection Type Surface Emitting Lighting

TECHNICAL FIELD The present invention relates to surface emitting illumination, and more particularly, to illumination for surface emitting a large area of an LED (light emitting diode) in which point emission occurs.

The light emitting diode is used in various fields because of the advantage that the light emitting efficiency is very good compared to a general light bulb. Light-emitting diodes not only function as illumination to illuminate the areas where people live, but are also widely used in industrial fields such as semiconductor exposure equipment.

However, light emitting diodes are close to intensive point lighting. Since such point lighting is very high in brightness, it is inappropriate to use it as a direct light, and the eye may be damaged if a person looks directly at it. Accordingly, an illumination structure for indirectly surface-emitting light emitting diodes that emit light is widely used.

Most of this type of surface-emitting illumination uses a light guide plate and a prism sheet to widen the light emitting area and guide the light emitting direction forward to increase the luminance.

In addition, in order to implement surface emission, a method of evenly distributing and mounting the light emitting diodes in an area corresponding to the emitting surface is also used.

However, the optical member or prism sheet such as a light guide plate has a problem of high cost because of the high cost, and arranging the light emitting diode corresponding to the light emitting area requires the use of more light emitting diodes as the surface emitting area increases. there is a problem.

Due to this problem, a structure that implements surface emission after installing a light emitting diode at a corner and irradiating light to the side has been used. However, since the use of a light guide plate and a prism sheet is inevitable, the cost of lighting is inevitably increased. .

Patent Registration No. 1829098 Patent Registration No. 1193503 Utility Model Registration No. 483741

The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a lighting apparatus capable of minimizing the number of installations of the light emitting diodes and sufficiently surface emitting light even if the light guide plate and the prism sheet are omitted.

In addition, an object of the present invention is to provide a lighting device that is easy to manufacture and compact, and can greatly reduce the cost.

In addition, an object of the present invention is to provide a lighting device that can be used in an optimal illumination state by flexibly deforming the surface emitting light emitting surface.

Moreover, an object of this invention is to provide the surface-emitting illumination apparatus which can raise a brightness largely, without using a prism sheet.

In order to solve the above-described problems, the present invention, the light source 30 is disposed on the side, the reflecting member 10 which is almost horizontal to the direction of incidence of the light source 30, but inclined by a very slight angle (a) Is installed next to the light source 30, to provide a lighting device constituting a light emitting surface 20, a predetermined virtual or actual surface disposed in front of the reflective member 10 surface emitting. In addition, the light source 30 is disposed on the side, and the light emitting surface 20 and the reflecting member 10 are both parallel to the incident direction of the light source 30, while the light emitting plate and the prism sheet do not have a high luminance surface light emission. It is intended to provide this possible lighting device.

The light emitting surface 20 may be disposed parallel to the representative light output direction of the light source 30. The light emitting surface 20 is arranged parallel to the reflecting member 10 or in parallel with the reflecting member 10 while being inclined by a very slight angle a. Then, the lighting device has a light emitting surface having a large area (L) corresponding to the light emitting surface 20, the overall thickness is as thin as the thickness (w) of the light source 20, it is possible to produce a light illumination.

The reflective member 10 forms a reflective profile surface 13 on which the first reflective surface 14 and the second reflective surface 15 are alternately disposed on the first surface of the UV curable synthetic resin film, and reflectance on the surface thereof. By depositing a metal such as this excellent aluminum can be produced in a thickness of approximately 0.05mm to 2.5mm. More preferably, it can be produced in a thickness of about 0.25mm to 1mm. Then, the surface of the light source can be realized by attaching the film at an angle to the side of the light source or by simply attaching the light source to the side of the film.

The first reflective surface 14 reflects light incident from a light source onto the second reflective surface 15, and the second reflective surface 15 reflects light reflected from the first reflective surface to the light emitting surface ( 20).

The first reflective surface 14 is a profile in which light incident on the first reflective surface may be evenly reflected to the second reflective surface, and may include a convex curved surface, a concave curved surface, or a plane.

The second reflective surface 15 may have a concave curved profile that may reflect light reflected from the first reflective surface to be substantially perpendicular to the light emitting surface 20.

In addition, between the first reflective surface 14 and the second reflective surface 15, and / or between the second reflective surface 15 and the first reflective surface 14, the first reflective surface is independent of the reflection of light. Connection surface 16 may be further provided to allow the separation distance between the second reflective surface. In particular, this connecting surface 16 makes it possible to set the angle a smaller, or to make the luminance near and far from the light source uniform.

In applying the film-like reflective member, the first surface of the reflective member, that is, the surface of the reflective profile surface 13 may be used as the reflective surface, or the rear surface may be used as the reflective surface. For example, if the reflection profile surface 13 is installed facing the light source, the surface can be used as the reflection surface. On the contrary, when the second surface, which is the opposite surface of the first surface, is installed to face the light source, and the film member 11 is made of a light transmissive material, the rear surface of the reflective profile surface 13 can be used as the reflective surface. .

Of course, the present invention does not exclude the use of optical members such as light guide plates and diffusion plates. The present invention can realize high luminance surface light emission without using the light guide plate and the diffuser plate, and in addition, if the light guide plate and the diffuser plate are used, of course, higher quality surface light emission can be achieved. This is a clear distinction from the conventional lighting device to implement surface light emission using a light guide plate and a diffusion plate.

LED may be used as the light source 30.

More specifically, the present invention provides an illuminating device for surface emitting light, comprising: a reflecting member 10 arranged at a predetermined angle (a) of 0 to 45 degrees with respect to the surface emitting light 20; And a light source 30 irradiating light toward the reflective member 10 between the light emitting surface and the reflective profile surface 13 of the reflective member 10.

The reflective member 10 may include: a film member 11 having a first surface having the reflective profile surface 13 and a second surface facing the first surface; And a first reflection surface 14 and a second reflection surface 15 which are alternately provided on the surface of the reflection profile surface 13 along the longitudinal direction of the film member.

The incident light 61 emitted from the light source 30 is incident on the first reflective surface 14, and the primary reflected light 62 on which the incident light 61 is reflected on the first reflective surface 14 is Is incident on a second reflective surface 15 adjacent to the first reflective surface 14 and disposed closer to the light source 30 than the first reflective surface 14 and at the second reflective surface 15. The secondary reflected light 63 reflected by the primary reflected light 62 intersects the incident light 61 and exits toward the emission surface 20.

The film member 11 may be made of a flexible light transmitting material.

The film member 11 includes a base film layer 17 having a predetermined thickness and a reflection pattern shape layer 18 that is laminated on the surface of the base film 17 to form the reflection profile surface 13. It may include.

Metal or reflective ink may be applied to the reflective profile surface 13 to form the first reflective surface 14 and the second reflective surface 15.

A connection surface 16 may be further provided between the first reflective surface 14 and the second reflective surface 15 which are alternately arranged.

The first reflecting surface 14 comprises a convex, flat or concave surface profile when viewed from the direction of light irradiation, and the second reflecting surface 15 of the concave curved surface when viewed from the direction of light irradiation. It may include a profile.

As an example, the incident light 61 enters the first reflective surface 14 toward the surface of the reflective profile surface 13 via a medium, and the primary reflected light 62 passes through the medium to the reflective profile. The second reflective surface 15 may be incident toward the surface of the surface 13, and the secondary reflected light 63 may be emitted to the emission surface 20 through the medium.

In this case, the medium may be air or a fluid medium 70.

To this end, the lighting device is configured such that the light emitting surface 36 of the light source 30 is disposed between the first end positioned close to the light emitting surface 20 and the second end positioned far from the light emitting surface. The light source mounting portion 81 to which the 30 is fixed, and the reflecting member 10 face the emission surface 36 and the light emitting surface 20 of the light source 30 installed in the light source mounting portion 81. It may include a housing 80 having a reflective member mounting surface 82 for fixing.

The housing 80 may further include a cover 85 that divides the medium from an external space of the lighting apparatus and includes a transparent material or a diffusion plate.

In addition, the cover 85 may form the light emitting surface 20.

As another example, the incident light 61 passes through the second surface of the film member 11 and the film member 11 toward the rear surface of the reflective profile surface 13. Is incident on the second reflective surface 15 through the film member 11 toward the rear surface of the reflective profile surface 13, and the secondary reflected light 63 is incident on the second reflective surface 15. The light emitting surface 20 may be emitted to the light emitting surface 20 through the film member 11 and the second surface.

The surface emitting illumination device may further include an optical member 50.

The optical member 50 may include: a light source installation unit 81 facing the emission surface 36 of the light source 30 to receive light from the light source; A reflective member mounting surface 82 facing the second surface of the film member 11; And the light emitting surface 20 through which the light reflected from the reflective member 10 is emitted.

In particular, the light source mounting portion 81 and the reflective member mounting surface 82 may be adjacent to each other, and the light source mounting portion 81 and the light emitting surface 20 may be adjacent to each other.

As another example, the incident light 61 is incident on the film member 11 through the side surface of the film member 11, and passes through the film member 10 toward the rear surface of the reflective profile surface 13. Incident on the first reflective surface 14, the primary reflected light 62 is incident on the second reflective surface 15 toward the rear surface of the reflective profile surface 13 via the film member 11, and the second The reflected light 63 may be emitted to the light emitting surface 20 through the second surface of the film member 11.

As another example, the incident light 61 is incident on the base film layer 17 through a side surface of the base film layer 17, and passes through the base film layer 17 to the base film layer 17. ) Is incident on the reflective pattern layer 18 through an interface between the reflective pattern layer 18 and the first reflective surface toward the rear surface of the reflective profile surface 13 via the base film layer 17. Incident to the second reflective surface 15 through the reflective pattern layer 18 and toward the rear surface of the reflective profile surface 13. The reflected light 63 may be emitted to the light emitting surface 20 through the second surface of the film member 11.

In the above examples, the predetermined angle a may be 0 degrees.

Also, in the above examples, the second surface may be the light emitting surface 20.

The light emitting surface 20 may include a diffusion plate.

The refractive index N1 of the base film layer 17 and the refractive index N2 of the reflective pattern shape layer 18 may satisfy the formula of N1 = N2.

In addition, more preferably, the formula of 0.05 = N2-N1 = 0.69 can be satisfied.

According to the surface-emitting lighting apparatus of the present invention, even if an optical member such as a light guide plate or an expensive component such as a prism sheet is not used, and a high-precision reflective surface is not used, the surface-emitting lighting apparatus of high brightness only by the reflective member in the form of a film There is an advantage that can be implemented.

Accordingly, the present invention can simplify the structure of the surface-emitting lighting apparatus, can be easily manufactured at low cost, and can be manufactured at a very light weight.

In addition, by allowing the film layer of the reflective member in the form of a film to have the function of the light guide plate, it is possible to flexibly deform the light emitting surface.

In addition to the effects described above, the specific effects of the present invention will be described together with the following description of specifics for carrying out the invention.

1 is a cross-sectional view showing a first embodiment and a second embodiment of a film-shaped reflective member used in the lighting apparatus according to the present invention.
FIG. 2 is a view illustrating a principle of surface light source of a point light source through the reflection profile surface of the reflective member of FIG. 1.
3 is a cross-sectional view showing a third embodiment and a fourth embodiment of the film-shaped reflective member used in the lighting apparatus according to the present invention.
FIG. 4 is a view illustrating a principle of surface light source of a point light source through the reflection profile surface of the reflective member of FIG. 3.
5 is a view showing various structures that can be used as a light source of the lighting apparatus of the present invention.
6 is an exploded cross-sectional view conceptually showing the first embodiment of the lighting apparatus of the present invention.
7 is a cross-sectional view of the assembled state of the lighting apparatus shown in FIG.
8 is an exploded cross-sectional view conceptually showing a second embodiment of the lighting apparatus of the present invention.
9 is a cross-sectional view of the assembled state of the lighting apparatus shown in FIG.
10 is an exploded cross-sectional view conceptually showing a third embodiment of the lighting apparatus of the present invention.
11 is a cross-sectional view of the assembled state of the lighting apparatus shown in FIG.
FIG. 12 is a schematic diagram partially showing an enlarged third embodiment of FIG.
14 is a view showing a manufacturing process of the reflective member used in the fourth embodiment according to the present invention.
FIG. 15 is a diagram schematically illustrating a structure of implementing a surface-emitting lighting apparatus using the reflective member shown in FIG. 14.
15 is a diagram illustrating a modification of FIG. 14.
16 and 17 are diagrams showing modifications of the reflective member of FIG. 14.

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

The present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, only this embodiment to make the disclosure of the present invention complete and to those skilled in the art to fully understand the scope of the invention It is provided to inform you.

[Purpose Light Emitting Principle]

Hereinafter, the principle of implementing the surface emission of the lighting apparatus according to the present invention will be described with reference to FIGS. 1 to 5.

The lighting apparatus of the present invention includes a reflecting member 10 for diffusing and reflecting light incident at an oblique angle in a narrow width. The reflective member 10 may be manufactured in the form of a film.

1 shows a partially enlarged view of the reflective member 10 in the form of a film. The reflective members 101 and 102 in the form of films shown in FIGS. 1A and 1B, respectively, include a first surface on which a reflective profile surface 13 is formed and a second surface used as an attachment surface 12. It includes a film member 11 provided.

The film member 11 may be made of a synthetic resin material having high flexibility and high light transmittance. It may be a UV curable resin of PE material. The reflective profile surface 13 provided on the upper surface (first surface) of the film member 11 may be manufactured or molded through surface processing in the step of manufacturing the film with synthetic resin. The lower surface (second surface) of the film member 11 may be easily attached, and in some cases, may be manufactured as a flat surface to prevent scattering and reflection of light that may be incident on the film member 11 through the lower surface. .

The reflective profile surface 13 may be coated with a metal having a very high reflectance such as silver or aluminum by deposition or sputtering through CVD or the like. In addition, white reflective ink may be applied to the reflective profile surface 13 by dipping or the like.

The metal reflective layer coated on the reflective profile surface may not only reflect light radiated from the upper portion of the film on the surface of the first surface, but also receives light introduced through the film member from the lower surface of the film on the rear surface of the first surface. It can also reflect from the surface. The film shown in (a) of FIG. 1 is a structure intended to reflect light from the surface of the first surface, and the film shown in (b) is a structure intended to reflect light from the rear surface of the first surface. . All of these reflective profile surfaces are easy to manufacture.

FIG. 2 shows the principle that the light of a narrow area is broadly turned into a surface light source by the reflective profile surface 13 of the film shown in FIG. 1.

The reflective profile surface 13 may be alternately disposed between the first reflective surface 14 and the second reflective surface 15, and may further include a connection surface 16 for adjusting a distance or position between these reflective surfaces. have.

The light source 30 may radiate light obliquely toward the reflective member 10 from the side of the reflective member 10. In addition, the reflective member 10 may be disposed in a state inclined at a slight angle (a) with respect to the light source. In FIG. 2, the light source 30 irradiates light in a horizontal direction as shown, and the reflecting member 10 reflects the light upwardly and vertically to convert the light irradiated into a narrow area into a surface light source. In theory, the light emitting area of the reflective member 10 may be increased by cot a times compared to the light emitting area of the light source 30.

In this way, the reflective member 10 is provided such that its reflective surface faces the emission surface 36 of the light source 30 and also the emission surface 20. In other words, the reflective surface of the reflective member 10 is disposed obliquely with respect to the incident direction of the light source 30 and is disposed in the form of an inclined surface which is obliquely disposed with respect to the light emitting surface 20.

When the reflective member 10 is inclined at an angle of a and is installed obliquely next to the light source 30, when the reflective member 10 is viewed in the horizontal direction from the light source 30, a plurality of first reflective surfaces ( Only 14) are exposed. When the reflective member 10 is viewed vertically downward from the upper portion of the drawing, only the plurality of second reflective surfaces 15 are exposed.

In FIG. 2, the light source 30 irradiates light horizontally, and the reflective member 10 is installed to be inclined by a predetermined angle a, but this is a relative concept. That is, the light source 30 may be installed downward from the horizontal by a predetermined angle a, and the reflective member 10 may be horizontal. Accordingly, the pattern of the reflective surface of FIG. 2 may also be slightly inclined (see FIG. 17).

The convex curved surface of the first reflecting surface 14 receives incident light 61, 611, 612, and 613 incident side by side in parallel in a horizontal direction from the light source 30 toward the first reflecting surface 14. The two reflection surfaces 15 are evenly distributed and reflected. In addition, all of the primary reflected light 62 reflected by the first reflective surface is reflected substantially upwardly in the drawing on the second reflective surface 15 of the concave curved surface. That is, the secondary reflected light 63 (631, 632, 633) reflected from the second reflective surface 15 becomes parallel light distributed more widely.

The smaller the installation angle a of the reflective member 10 is, the larger the surface emission enlarged area becomes. The connecting surface 16 may set the distance between the first reflective surface 14 and the second reflective surface 15 of the reflective member 10 to be wider, and the two reflective surfaces in the horizontal direction as well as the vertical direction in the drawing. It is possible to set the distance between (14, 15). Such a connecting surface 16 makes it easier to make the installation angle a of the reflecting member 10 smaller while being involved or not involved in reflection. In Fig. 2, the connecting surface 16 is shown not functioning as the intended reflecting surface. However, since the light irradiated from the light source is not completely parallel light, as a result, the surface of the connecting surface 16 may also be involved in reflection.

2 illustrates a structure in which the connecting surface 16 is disposed between the first reflective surface 14 and the second reflective surface 15 which transmit and receive reflected light to each other, but the connecting surface 16 may transmit and receive reflected light to each other. However, it may be located between the neighboring second reflective surface 15 and the first reflective surface 14, or both may be located.

3 shows a partially enlarged view of another embodiment of the film-shaped reflective member 10. The reflective members 103 and 104 in the form of films shown in FIGS. 3A and 3B, respectively, also have a first surface on which the reflective profile surface 13 is formed and a second surface used as the attachment surface 12. It includes a film member 11 having a.

The reflective layer coated on the reflective profile surface 13 may not only reflect light emitted from the upper portion of the film on the surface of the first surface on the drawing, but also transmit the light introduced through the film member from the lower surface of the first surface. It can also reflect from the back of the. The film shown in (a) of FIG. 3 is a structure intended to reflect light from the surface of the first surface, and the film shown in (b) is a structure intended to reflect light from the rear surface of the first surface. . All of these reflective profile surfaces are easy to manufacture.

In the reflection profile surface 13, the first reflection surface 14 and the second reflection surface 15 are alternately arranged. In the embodiment shown in FIG. 3, an example is shown in which the connecting surface 16 for adjusting the distance or position between these reflective surfaces is not provided. However, the connecting surface 16 may be added (see FIG. 15). ).

Referring to FIG. 4, the light source 30 irradiates light in the horizontal direction from the side of the reflective member 10, and the reflective member 10 installed obliquely next to the light source 30 reflects the light upward and vertically. By reflecting, the light irradiated with a narrow area becomes a wide surface light source.

When the reflective member 10 is inclined at an angle of a and is installed obliquely next to the light source 30, when the reflective member 10 is viewed in the horizontal direction from the light source 30, a plurality of first reflective surfaces ( Only 14) are exposed. When the reflective member 10 is viewed vertically downward from the upper portion of the drawing, only the plurality of second reflective surfaces 15 are exposed.

In FIG. 4, the light source 30 irradiates light horizontally, and the reflective member 10 is installed to be inclined by a predetermined angle a, but this is a relative concept. That is, the light source 30 may be installed downward from the horizontal by a predetermined angle a, and the reflective member 10 may be horizontal. Accordingly, the pattern of the reflective surface of FIG. 4 may also be slightly inclined (see FIG. 16). In addition, when the reflecting member itself functions as a light guiding function, the light source may be arranged horizontally and the reflecting member may be arranged horizontally.

The concave curved surface of the first reflective surface 14 may include incident light 61 (611, 612, 613) incident side by side in parallel in a horizontal direction from the light source 30 toward the first reflective surface 14. The two reflection surfaces 15 are evenly distributed and reflected. In addition, all of the primary reflected light 62 reflected by the first reflective surface is reflected substantially upwardly in the drawing on the second reflective surface 15 of the concave curved surface. That is, the secondary reflected light 63 (633, 632, 631) reflected from the second reflective surface 15 becomes parallel light distributed more widely.

The two reflective surfaces 14 and 15 which are adjacent to each other to transmit and receive reflected light are repeatedly installed as a unit, and a connecting surface is disposed between these units, or a connecting surface is disposed inside the units, or between the units. As described above, all of the connection surfaces may be disposed inside the unit.

1 and 2, the first reflective surface is a convex curved surface and the second reflective surface is a concave curved surface, and as shown in FIGS. 1 and 2, both the first reflective surface and the second reflective surface are Irrespective of the concave curved surface, the angle r1 at which the incident light 61 irradiated from the light source is reflected by the first reflective surface 14 and the primary reflected light 62 reflected by the first reflective surface 14 are reflected. The sum of the angles r2 reflected from the second reflective surface 15 is set to be close to 90 degrees to 90 degrees. For example, if the reflection angle r1 of the primary reflected light 62 is 89 degrees (see 613 of FIG. 2 and 611 of FIG. 4), the reflection angle r2 of the corresponding secondary reflected light is 1 degree (see FIG. 2). 633 and 631 of FIG. 4), if the reflection angle r1 of the first reflected light is 45 degrees (see 612 of FIG. 2 and 612 of FIG. 4), the reflection angle r2 of the corresponding second reflected light is 45 degrees. 2 (see 632 in FIG. 2 and 632 in FIG. 4), and the reflection angle r1 of the first reflected light is 1 degree (see 611 in FIG. 2 and 613 in FIG. 4). ) Is 89 degrees (see 631 in FIG. 2 and 633 in FIG. 4).

In order to satisfy such a rule, for example, referring to FIG. 4, the inclination of the first point b11 of the first reflective surface area B1 to which the incident light 61 is incident is 90 degrees, and the second point b12 of FIG. The slope has a profile of -45 degrees, and in order to make the angle of a very small, it is preferable that the first reflective surface has a concave profile.

In addition, the inclination of the first point b21 of the second reflection surface area B2 on which the primary reflected light 62 is incident is -45 degrees, and the slope of the second point b22 is 0 degrees. In order to make the angle of a very small, it is preferable that the second reflective surface has a concave profile.

The reflection surface profile may be set in the same manner as in FIG. 2. As a result of the inventor's research, when the first reflective surface is convexly formed as shown in FIGS. 1 and 2, the first reflective surface is more compact than the concave first reflective surface as shown in FIGS. 3 and 4. It is possible to configure. In addition, when the first reflective surface has a convex profile, the light reflected from the second reflective surface spreads more uniformly even if the degree of incidence of the incident light of the light source 30 is somewhat less than that of the concave profile. It was found to be easier to have.

On the other hand, even if the first reflective surface 14 forms a flat plane without being convex or concave, it is possible to realize surface emission as intended in the present invention. Since the surface light emission of the illumination is not necessarily implemented by irradiating light perpendicular to the light emitting surface 20, even if the first reflective surface 14 is a plane, the surface profile of the reflection 13 for realizing the surface light emission is achieved. There is no problem.

When the first reflection surface and the second reflection surface profile are set to have the reflection angle as described above, the surface is converted into a light source in a reflective manner, but occupies a narrow space without an optical member such as a light guide plate or a diffuser plate, and forms a parallel light. It is possible to make the surface light source. By satisfying these conditions and forming a small inclination angle (a) of the reflective member 10, the lighting device can be made slim, and the surface area can be realized by expanding the light emitting area at the ratio of cot a. Do.

In the lighting device, the light source 30 and the reflecting member 10 may be installed in the housing 80 to be described later and fixed to each other and may be assembled or installed in the optical member 50 to fix the relative positions to each other. In addition, the light source 30 may be directly fixed to the reflective member 10.

The light source 30 is a light reflecting plate 34 or a lens (as shown in FIG. 5), rather than the light irradiated from the LED, which is the light emitting unit 31 mounted on the substrate 32, directly incident on the reflecting member 10. Through the light collecting part 33 as shown in FIG. 35, the light may be incident to the reflective member 10 by being in the form of parallel light to some extent. At this time, the direction of the light emitting portion 31 is disposed to face the reflective member 10 as shown in (b) or (c), or as shown in (a) is arranged in a direction facing the surface emitting surface The reflective member 10 may be disposed against the back. In addition, the reflector 34 may be provided at one side as shown in (a) of FIG. 5 or both at both sides as shown in (b), and the lens 35 may be integrally packaged on a substrate. .

The light that has been condensed to some extent is emitted through the emission surface 36 of the light source and is incident on the reflective member 10.

[First Embodiment]

Hereinafter, a first embodiment of a lighting apparatus to which the surface light emission implementing principle of the present invention is applied will be described with reference to FIG. 6. In the first embodiment, a lighting apparatus employing a structure in which reflection occurs on the surfaces of the reflective members 101 and 103, that is, the reflective profile surface 13, as shown in FIG. Is illustrated.

The light source 30 and the reflective member 10 may be installed in the housing 80 and their positions may be fixed to each other.

The housing 80 includes a light source mounting unit 81 on which the light source 30 is installed, and a reflective member mounting surface 82 on which the reflective member 10 is installed. In addition, the space having a cross section of a substantially right triangle shape provided on the rear surface of the reflective member mounting surface 82 may be an accommodation part 84 in which the control unit 40 for controlling the light source 30 is installed.

The housing 80 may define a cuboid space having a width of approximately L and a depth of w.

One flat reflective surface turns the angle of incidence of the light by the angle of reflection with respect to the incident light, but has no effect of condensing. In addition, reflective surfaces such as convex mirrors disperse incident light, but are not suitable for surface light emission because they are not in parallel light form. In addition, the surface light emitting method using an optical member such as a light guide plate may have a large degree of reflection or loss of light while transmitting light between a dense medium and a small medium, and thus, a manufacturing cost and a weight of lighting may be increased.

However, in the lighting apparatus of the present invention, the structure in which the light emitting area of the light source is enlarged by cot a = L / w is simply attached to the side of the light source 10 irradiated laterally at an angle of a with the film-like reflective member 10. It is completed by installing.

In addition, the space corresponding to the right triangular portion can be utilized as the housing portion 84 of the housing 80, and it is possible to install various electrical appliances such as the control portion 40 in this portion, so that the overall compact and slim surface emitting light Device design is possible.

In addition, a cover 85 covering the light source and the reflective member may be further installed at a position corresponding to the light emitting surface 20 of the lighting device to block foreign matter from entering the surface of the reflective member.

The cover 85 may be simply made of a transparent material, a shape for dispersing light such as liver glass, or a diffuser plate material. The cover 85 having a structure such as a diffusion plate may further improve the quality of surface emission. Of course, since the surface is already light-emitting by the reflective member, the cover 85 can be omitted.

Second Embodiment

Hereinafter, a first embodiment of a lighting apparatus to which the surface light emission implementing principle of the present invention is applied will be described with reference to FIGS. 8 and 9. In the description of the second embodiment, a description of duplicated matters with the first embodiment will be omitted.

In the second embodiment, in addition to the first embodiment, an optical structure is implemented by filling a fluid medium 70 such as a liquid between the front surface of the reflective member 10 and the cover 85.

According to the second embodiment, after the reflective member 10 is installed in the housing 80, the fluid medium 70 is filled in the space in front of the reflective member 10 so that the fluid medium 70 does not leak. It is sealed by the cover 85. The fluid medium 36 then penetrates and fills the space between the pattern of the first reflective surface 14 and the second reflective surface 15.

The light source 30 may be installed to be replaceable regardless of the space in which the fluid medium 70 is filled.

According to the second embodiment, the light of the light source 30 passes through the fluid medium 70 and reaches the surface of the first reflective surface 14 of the reflecting member 10.

Incident light reaching the surface of the first reflective surface 14 is reflected and is incident on the second reflective surface 15 adjacent to the first reflective surface 14 through the fluid medium 70. Secondary reflected light reflected from the second reflective surface 15 is reflected as substantially parallel light, and passes through the fluid medium 70 and is emitted as illumination light through the light emitting surface 20.

According to such a structure, the phenomenon that the surface of the reflective member 10 is contaminated can be prevented. In addition, there is an advantage that the incident light irradiated with a slight error from the light source 30, totally reflected from the light emitting surface 20 of the fluid medium 70 or the cover 85 to be incident on the reflective member 10 (Fig. 12). Reference). Above all, such a structure is better in that it can have an effect similar to the light guide plate without an expensive optical member such as the light guide plate.

In order to minimize reflection and refraction at the boundary between the cover 85 and the fluid medium 70, the density of the cover and the fluid medium is preferably set to be similar to each other. In other words, the material of each medium may be adopted to have a similar density.

Third Embodiment

10 to 12, a third embodiment of a lighting apparatus to which the surface light emission implementing principle of the present invention is applied will be described. In the third embodiment, the illumination device to which the reflection member 102, 104 as shown in Fig. 1 (b) or Fig. 3 (b), that is, a structure in which reflection occurs on the back surface of the reflection profile surface 13 is applied. Is illustrated.

In the third embodiment, the optical member 50 is installed in a space where the reflective member 10 and the light source 30 face each other, and the light source mounting portion 81 and the reflective member mounting surface 82 are disposed on the optical member. And the light emitting surface 20 are all different from the structure in which the light source 30 and the reflective member 10 are installed in the housing 80. The optical member 50 may be made of a material having good light transmittance, such as acrylic. In addition, the emission surface 36 of the light source 30 and the emission surface 20 of the lighting apparatus may be perpendicular to each other, and thus, may have a structure having an elongated right triangle cross section.

The bonding portion of the optical member 50 and the reflective member 10 may be bonded through an optical adhesive (OCR / OCA) 90 having a density similar to that of the optical member and having good transmittance.

In addition, in the third embodiment, there is a difference in that the reflective surface of the reflective member 10 occurs on the rear surface of the reflective member 10 instead of the surface of the reflective member 10. In other words, in the film constituting the reflective member 10 of the third embodiment, the reflective surface becomes the first surface, that is, the back surface of the reflective profile surface 13. The light emitted from the light source 30 passes through the optical member 50, the optical adhesive 90, and the film member 11 of and reaches the first reflective surface 14 behind the reflective profile surface 13.

Since the reflective member deposits aluminum on the surface of the synthetic resin film in which the reflective surface profile is formed on the surface, the reflective surface passes through the synthetic resin portion of the film on the back side of the film as well as when the light is directly irradiated on the reflective surface profile from the outside of the film. Even if light is irradiated on the back side of the profile, reflection may occur.

Incident light reaching the rear surface of the first reflective surface 14 is reflected and is incident on the rear surface of the second reflective surface 15 through the synthetic resin portion of the film member 11. The secondary reflected light reflected from the rear surface of the second reflective surface 15 is reflected by substantially parallel light, and passes through the synthetic resin portion, the optical adhesive 90 and the optical member 50 of the film member, and the light emitting surface. It is irradiated to the outside of the lighting device through 20.

In order to minimize reflection and refraction between the boundary between the film member and the optical adhesive and between the boundary between the optical adhesive and the optical member, the density of the film member, the optical adhesive and the optical member is preferably set to be similar to each other. In other words, the material of each medium may be adopted to have a similar density.

According to the third embodiment, since the light source 30 and the reflective member 10 can be fixed by the optical member 50, the configuration of the housing 80 of the configuration illustrated in the first embodiment It is possible to omit or to manufacture in a different form.

When the optical member 50 is further provided as in the third embodiment, the phenomenon that the rear surface of the reflective profile surface 13, which is the reflective surface of the reflective member 10, can be prevented. In addition, as shown in FIG. 12, the incident light irradiated with a slight error from the light source 30, is totally reflected on the light emitting surface 20 of the optical member 50 or the cover 85, and is incident on the reflective member 10. Have the advantage of being

In the illustrated third embodiment, the case where the predetermined angle a is a small acute angle is illustrated, but the predetermined angle may be 0 degrees. That is, even when the reflective member 10 and the light emitting surface 20 are parallel, since the light emitted from the light source 30 is not the parallel light, but the diffuse light, the light emitted from the light source 30 Eventually, all of them may be reflected by the reflective member 10 and used as illumination light through the light emitting surface 20.

That is, in the present invention, the light emitted by the light source 30 in parallel means light parallel to the light emitting surface 20 directly from the light source 30, as shown in FIG. This may be understood as a concept including light that is totally reflected and can be returned to the reflecting member 10, that is, light that spreads at an angle equal to or greater than the total reflection critical angle.

Unlike the conventional light guide plate, the optical member of the third embodiment does not perform panel processing by printing or laser patterning under the light guide plate. Therefore, the material itself may be similar to the conventional light guide plate, but it is worth noting that there is no need to perform any panel processing that causes a price increase.

Fourth Embodiment

Hereinafter, referring to FIGS. 13 to 17, a fourth embodiment of a lighting apparatus to which the surface light emission implementing principle of the present invention is applied will be described. In the fourth embodiment, a structure in which reflection occurs on the back surface of the reflective members 102 and 104, that is, the reflection profile surface 13, as shown in FIG. 1 (b) or 3 (b) is applied. Illustrative is an illumination device in which light is incident on the side of the member so that the film member itself constituting the reflective member serves as a light guiding function.

First, referring to FIGS. 13 and 14, the reflective member 10 is manufactured in a form in which a reflective layer is deposited, coated, or painted on the reflective profile surface 13 of the film member 11. The film member 11 may be made of two or more different layers. This is not only because of the convenience of manufacturing, but also by the refraction of the light incident on the reflective surface at the boundary of the layers of different materials, and finally, the straightness of the light emitted from the light emitting surface 20 can be further increased, thereby increasing the luminance. Have

The film member 11 is UV cured by laminating and molding the reflective pattern forming layer 18 constituting the reflective profile surface 13 on the base film layer 17 having a predetermined thickness (about 0.5 mm) with a mold resin. Can be produced in a manner. The base film layer 17 may be made of a flexible material such as polycarbonate (PC). Therefore, the film member 11 may be manufactured in the form of a flexible sheet.

The reflective pattern forming layer 18 may be formed by molding a soft synthetic resin on the base film layer 17 and then UV curing. A reflective layer may be coated on the reflective profile surface 13 formed by stacking the reflective pattern forming layer 18 on the first surface of the base film layer 17. The reflective layers 14 and 15 may be coated by depositing silver, aluminum, or the like which forms a reflective surface well or by applying reflective ink.

The base film layer 17 and the reflective pattern forming layer 18 may be made of the same or different materials. According to the fourth embodiment, each material may be selected such that the refractive index N1 of the base film layer 17 is less than or equal to the refractive index N2 of the reflective pattern forming layer 18, that is, N1 ≤ N2. have.

According to the fourth embodiment, there is illustrated a structure in which reflection occurs on the back surface of the reflective surface. If the refractive index of the base film layer is larger than that of the reflective pattern forming layer, that is, if N1> N2, the reflection in the base film layer Since a part of the light incident on the pattern forming layer is larger than the critical angle, the phenomenon that the light cannot be incident on the reflective pattern forming layer occurs, thereby reducing the amount of light reflecting the light to the light emitting surface 20 through the double reflection surface.

Even if the film member 11 manufactured as described above has a predetermined angle a of the reflective member 10 with respect to the light emitting surface 20 being 0 degrees, that is, the film member 11 and the light emitting surface 20 are parallel to each other. Surface light emission can be made brighter. That is, in the above embodiments, the predetermined angle (a) is about 2 to 3 degrees to secure the angle of the light incident on the first reflective surface 14 to some extent, between the base film layer and the reflective pattern forming layer. If refraction occurs and refraction occurs at an interface having a larger refractive index than the base film layer, the angle of light incident on the first reflective surface 14 may be additionally secured by the refraction at the interface.

Therefore, as shown in FIG. 14, the second surface of the film member 11 forms the light emitting surface 20 and the first surface of the film member 11 having the reflective surfaces 14 and 15 of the film member 11 is the second surface. Even if the light source 30 irradiates light in a direction parallel to the first surface and the second surface from the side of the film member 11 between them, the refraction occurs, so that the reflective member is moved by a predetermined angle. It can have an effect similar to that tilted.

The light source 30 may be a thin light source corresponding to the thickness of the film member, which may be implemented as an LED. The light source 30 irradiates slightly diffused light, rather than a completely parallel light source, of which the incident light 61 first reaching the second surface of the film member 11 is totally reflected at the second surface to form a base film layer ( 17) and the reflective pattern forming layer 18.

And at the interface, the incident light 61 is refracted in the direction shown, reaching the first reflective surface 14. The primary reflection light 62 reflected from the first reflection surface 14 is incident on the second reflection surface 15 again, and the secondary reflection light 63 reflected from the second reflection surface 15 is the emission surface 20. ), The exit is high. When the secondary reflected light is incident almost perpendicularly to the light emitting surface 20, the light is reflected at the interface between the air (upper space of the second surface) and the second surface of the film member and returns to the inside of the film member 11 again. The amount of can be minimized, and thus the luminance can be greatly increased. That is, according to the present invention, even if a conventional prism sheet (two sheets are stacked so that the prism shape is vertical) is used to induce the refraction of light to increase the brightness, so that sufficient luminance can be ensured. do.

On the other hand, the difference between the refractive index (N1) of the base film layer 17 and the refractive index (N2) of the reflective pattern layer 18 is preferably 0.69 or less, that is, N2-N1 = 0.69. When the refractive index difference (N2-N1) of the two layers (17, 18) exceeds 0.69, the refraction is large, and the range where the double reflection can easily occur on the first reflective surface 14 and the second reflective surface 15. Beyond That is, the refractive light of the incident light 61 incident on the first reflective surface 14 becomes too large. In addition, when the difference between the two layers exceeds 0.69, the amount of reflection that normally occurs at the interface between the two media increases rapidly and the amount of light passing through the interface between the two layers is drastically reduced.

Next, if the refractive index difference (N2-N1) of the two layers (17, 18) is less than 0.05, even if the refraction occurs at the interface of the two layers, the angle of refraction is not secured, as shown in Figure 14 the second surface 20 When the first surface is parallel and the light source 30 shines the light horizontally, the double reflection is not made smoothly.

14 shows a reflective profile surface 13 in which the first reflective surface 14 is planar. As described above, the first reflecting surface 14 serves to reflect the light incident from the light source to reach the second reflecting surface 15. In view of the object of the present invention, the first reflecting surface 14 realizes surface emission. Even if the reflecting surface 14 is formed flat, there is no significant effect on the occurrence of double reflection. However, rather than the case where the first reflective surface 14 has a concave or convex curved surface, the secondary reflected light 63 reflected from the second reflective surface 15 tends to diffuse slightly, which causes a slight decrease in luminance. It only causes On the contrary, when the first reflective surface 14 is formed flat, the reflective member 10 can be manufactured more easily, and the manufacturing cost can be greatly reduced.

FIG. 15 illustrates a structure in which the above-described connecting portion 16 is formed between the double reflection patterns 14 and 15 that match each other. On the surface of the connecting portion 16, a metal having high reflectance may be coated. Even though the connection part 16 is not coated with a metal having a high reflectance, when the incident light 61 irradiated from the light source 30 reaches the connection part 16 as shown in FIG. 15, it is reflected again (the metal coating). ) Or total reflection (if there is no metal coating) to reach the second surface 20 of the film member 11, and then totally reflected from the second surface to be irradiated to the reflective profile surface under the film member. Reflected.

The connecting portion 16 may be used to adjust the light distribution by adjusting the distribution of the double reflection pattern. For example, as the distance from the light source 30 decreases, the length or frequency of the connection part 16 may be reduced, thereby minimizing the difference in the amount of double reflection occurring at a place far or close to the light source.

FIG. 16 illustrates that the film member 11 having the concave structure of both the first reflective surface 14 and the second reflective surface 15 may also be applied. In FIG. 17, the first reflective surface 14 is convex. It is illustrated that the film member 11 having a surface and having a concave second reflective surface can also be applied.

If the film member itself has a function of light guiding as in the fourth embodiment, the surface emitting illumination device can be made thin like a film, and the surface of the surface emitting light itself can be flexibly deformed, so that the use of lighting is further extended. Can be.

As described above, the present invention has been described with reference to the drawings, but the present invention is not limited to the embodiments and drawings disclosed herein, and various modifications may be made by those skilled in the art within the scope of the technical idea of the present invention. It is obvious that modifications can be made. In addition, even if the above described embodiments of the present invention while not explicitly described and described the operation and effect according to the configuration of the present invention, it is obvious that the effect predictable by the configuration is also to be recognized.

10, 101, 102, 103, 104, 105: reflective member (film)
11: film member
12: Attachment surface
13: reflective profile surface
14: first reflective surface
15: second reflective surface
16: connecting surface
17: base film layer
18: reflective pattern shape layer
20: emitting surface
30: light source
31: light emitting unit (LED)
32: substrate
33: condenser
34: reflector
35: lens
36: exit surface
40: control unit
50: optical member
61, 611, 612, 613: incident light
62: primary reflected light
63, 631, 632, 633: secondary reflected light
70: fluid medium
80: housing
81: light source mounting portion
82: reflective member mounting surface
84: receiver
85: cover
90: optical adhesive

Claims (20)

As a surface emitting light device,
The lighting device is:
A reflection member 10 arranged at a predetermined angle (a) of 0 degrees or more with respect to the light emitting surface 20 emitting the surface; And
And a light source 30 irradiating light to the reflective member 10 between the light emitting surface and the reflective profile surface 13 of the reflective member 10.
The reflective member 10 is:
A film member (11) having a first surface having the reflective profile surface (13) and a second surface facing the first surface; And
And a first reflection surface 14 and a second reflection surface 15 which are alternately provided on the surface of the reflection profile surface 13 along the longitudinal direction of the film member.
The incident light 61 emitted from the light source 30 is incident on the first reflective surface 14,
The primary reflected light 62 reflecting the incident light 61 on the first reflecting surface 14 is adjacent to the first reflecting surface 14 and is closer to the light source 30 than the first reflecting surface 14. Is incident on the second reflective surface 15 disposed closer to the
The secondary reflection light 63 reflected by the primary reflection light 62 on the second reflection surface 15 intersects the incident light 61 and exits toward the emission surface 20. Luminous lighting device.
The method according to claim 1,
The film member 11 is a surface light emitting device is made of a flexible light transmitting material.
The method according to claim 2,
The film member 11 has a base film layer 17 having a predetermined thickness,
And a reflection pattern shape layer (18) stacked on the surface of the base film layer (17) to form the reflection profile surface (13).
The method according to claim 1,
A metal or reflecting ink is coated on the reflective profile surface (13) to form a first reflective surface (14) and a second reflective surface (15).
The method according to claim 1,
And a connection surface (16) is further provided between the first reflection surface (14) and the second reflection surface (15) arranged alternately.
The method according to claim 1,
The first reflective surface 14 comprises a convex, flat or concave surface profile when viewed in the direction of light irradiation,
The second reflective surface (15) is a surface-emitting illumination device, characterized in that it comprises a concave curved profile when viewed from the direction of light irradiation.
The method according to claim 1,
The incident light 61 is incident on the first reflective surface 14 via a medium toward the surface of the reflective profile surface 13,
The primary reflected light 62 is incident on the second reflective surface 15 via the medium toward the surface of the reflective profile surface 13,
And the secondary reflected light (63) is emitted to the light emitting surface (20) through the medium.
The method according to claim 7,
The medium is a surface-emitting illumination device, characterized in that the air or fluid medium (70).
The method according to claim 8,
The lighting device,
The light source 30 to which the light source 30 is fixed so that the emission surface 36 of the light source 30 is disposed between a first end located close to the light emitting surface 20 and a second end located far from the light emitting surface An installation unit 81,
Reflecting member mounting surface 82 for fixing the reflecting member 10 to face the emission surface 36 and the light emitting surface 20 of the light source 30 installed in the light source mounting portion 81
Surface-emitting lighting apparatus comprising a housing 80 having a.
The method according to claim 9,
The housing 80,
The cover further comprises a cover 85 which partitions the medium from the external space of the lighting device and comprises a transparent material or a diffusion plate.
Surface-emitting illumination device, characterized in that the cover (85) forms a light emitting surface (20).
The method according to claim 1,
The incident light 61 is incident on the first reflective surface 14 toward the rear surface of the reflective profile surface 13 via the second surface of the film member 11 and the film member 11,
The primary reflected light 62 is incident on the second reflective surface 15 toward the rear surface of the reflective profile surface 13 via the film member 11,
And the secondary reflected light (63) is emitted to the light emitting surface (20) via the film member (11) and the second surface.
The method according to claim 11,
The surface emitting illuminator further includes an optical member 50,
The optical member 50 is:
A light source installing unit 81 facing the emission surface 36 of the light source 30, into which light of the light source is incident;
A reflective member mounting surface 82 facing the second surface of the film member 11; And
And a light emitting surface 20 through which the light reflected from the reflective member 10 is emitted.
The light source mounting portion 81 and the reflective member mounting surface 82 are adjacent to each other,
The light source mounting portion 81 and the light emitting surface 20 are adjacent to each other
Surface-emitting lighting apparatus, characterized in that.
The method according to claim 1,
The incident light 61 enters the film member 11 through the side surface of the film member 11, and passes through the film member 11 toward the back surface of the reflective profile surface 13 toward the first reflective surface 14. ),
The primary reflected light 62 is incident on the second reflective surface 15 toward the rear surface of the reflective profile surface 13 via the film member 11,
And the secondary reflected light (63) is emitted to the light emitting surface (20) via the second surface of the film member (11).
The method according to claim 3,
The incident light 61 is incident on the base film layer 17 through the side of the base film layer 17, and passes through the base film layer 17 to form the base film layer 17 and the reflective pattern. Is incident on the reflective pattern layer 18 through an interface of the layer 18 and is incident on the first reflective surface 14 toward the back surface of the reflective profile surface 13 via the base film layer 17 and ,
The primary reflected light 62 is incident on the second reflective surface 15 toward the rear surface of the reflective profile surface 13 via the reflective pattern layer 18,
And the secondary reflected light (63) is emitted to the light emitting surface (20) via the second surface of the film member (11).
The method according to claim 13 or 14,
The predetermined angle (a) is a surface-emitting illumination device, characterized in that 0 degrees.
The method according to claim 13 or 14,
Surface-emitting illumination device, characterized in that the second surface is a light emitting surface (20).
The method according to claim 12 or 13 or 14,
The light emitting surface 20 is a surface light emitting device characterized in that it comprises a diffusion plate.
The method according to claim 14,
The refractive index N1 of the base film layer 17 and the refractive index N2 of the reflective pattern layer 18 are
N1 ≤ N2
Surface-emitting lighting apparatus, characterized in that to satisfy the formula.
The method according to claim 18,
The refractive index N1 of the base film layer 17 and the refractive index N2 of the reflective pattern layer 18 are
N2-N1 ≤ 0.69
Surface-emitting lighting apparatus, characterized in that to satisfy the formula.
The method according to claim 18,
The refractive index N1 of the base film layer 17 and the refractive index N2 of the reflective pattern layer 18 are
0.05 ≤ N2-N1
Surface-emitting lighting apparatus, characterized in that to satisfy the formula.

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