KR20160111134A - Lighting apparatus - Google Patents

Abstract

The present invention relates to a lighting apparatus capable of reducing harmful backlight towards houses close to the lighting apparatus. Specifically, the lighting apparatus comprises: a lighting module including a substrate and one or more light emitting diodes (LED) mounted on the substrate; one or more lens modules arranged in a lower side of the substrate, and reflecting or refracting light emitted from the LED; and a power supply unit electrically connected to the substrate. The lens module includes a module body, and one or more lenses formed in the module body and corresponding to the LEDs. To totally reflect at least a part of the light emitted from the LED towards a lower side of the module body within a predetermined longitudinal direction angle range, the module body including one or more reflection units projected out downwards from a lower surface of the module body is included.

Description

[0001]

The present invention relates to a lighting apparatus, and more particularly, to a lighting apparatus capable of reducing a back light and increasing a light efficiency through total reflection of light by a reflection unit provided in a lens module.

In general, incandescent lamps, discharge lamps, and fluorescent lamps are mainly used as light sources mainly used for lighting devices, and they are used for various purposes such as home use, landscape use, and industrial use.

In particular, resistive light sources such as incandescent lamps have low efficiency and high heat generation problems. In the case of discharge lamps, there are problems such as high voltage and high voltage. In fluorescent lamps, environmental problems caused by mercury use can be mentioned.

In order to solve the disadvantages of such light sources, there is a growing interest in light emitting diodes (LEDs) having many advantages such as efficiency, color diversity, and design autonomy.

A light emitting diode is a semiconductor device that emits light when a voltage is applied in a forward direction. It has a long lifetime, low power consumption, electrical, optical and physical characteristics suitable for mass production, and is rapidly replacing incandescent bulbs and fluorescent lamps.

The light emitting diode is also applied to an illumination device for illuminating a road (for example, a streetlight).

1 shows a general example of a lighting device (hereinafter also referred to as "street lamp") formed to illuminate a conventional road. 1, the X-axis direction is defined as the forward and backward directions, and the Y-axis direction is defined as the height direction.

Referring to Fig. 1, a conventional street light 1 may include a strut 2 and a lighting device 3 installed on the top of the strut.

The illuminating device 3 may be arranged to irradiate light downward toward the road R. [

That is, the streetlight 1 is installed on the sidewall S so as to irradiate the light toward the road R downward.

Further, the streetlight 1 may be formed so that light is irradiated not only on the road R but also on the sidewall S.

In other words, the light from the lighting device 3 provided in the streetlight 1 can be irradiated toward the road S and the roads R and the roads R in front of and behind the road R. [

On the other hand, in FIG. 1, it is general that residential facilities such as the house H are arranged on the opposite side of the road R from the left and right side deliveries S.

At this time, if the light from the lighting device 3 is irradiated toward the house H, there is a problem that light pollution may be caused to people residing in the house H.

In addition, in the case where a row of trees is located at the part where the house H is located, there is a problem that the light is illuminated by the light emitted from the lighting device 3,

Further, since the lighting apparatus 3 of the streetlight 1 is continuously driven from the time before the sleeping time until the time after the sleeping time, when the light from the lighting apparatus 3 is irradiated toward the house H, There is a problem that it can cause the life-span disorder of people living in the area (H).

For example, light irradiated toward the rear of the illuminating device 3 with respect to a virtual line crossing the illuminating device 3 in the vertical direction at the central portion of the illuminating device 3 is reflected by a back light Can be defined.

Particularly when the light from the lighting device 3 is incident on the house H (that is, the lighting device 3) located near the streetlight 1 (i.e., the lighting device 3) among the lights B and C irradiated toward the house H, (Hereinafter also referred to as "harmful back light") toward the house (the house shown in the left side in Fig. 1) may be the most problematic.

That is, assuming that the front-rear direction angle range of the light irradiated from the lighting device 3 is the same as the center of the lighting device 3, the house H located near the streetlight 1 is located above the harmful backlight B), it is easy to see the damage of light pollution.

The light efficiency of the light A irradiated toward the road S or the road S by the amount of the light B or C irradiated toward the house H from the lighting device 3 Optical density) may be lowered.

Therefore, the light from the lighting device 3 is concentrated in the area of the light A irradiated toward the road S or the maximum road R of the lights B and C irradiated toward the house H Studies on a method for simultaneously achieving an increase in light efficiency and preventing harmful backlight are continuing.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a lighting apparatus capable of reducing hazardous backlight directed toward a house located near a lighting apparatus.

It is another object of the present invention to provide a lighting apparatus capable of preventing light pollution to a house or a roadside tree located near a lighting apparatus (that is, behind the lighting apparatus) through harmful backlight reduction of the lighting apparatus (street lamp) .

It is also an object of the present invention to prevent a problem of sleeping disorder that may occur in a person residing in a house located near a lighting device (i.e., behind the lighting device) due to the harmful backlight of the lighting device.

It is another object of the present invention to provide an illumination device capable of increasing light efficiency or optical density of light irradiated toward a road below a lighting device.

The present invention provides a light emitting module including a substrate and at least one LED mounted on the substrate, At least one lens module disposed below the substrate and configured to refract or reflect light emitted from the LED; And a power supply unit electrically connected to the substrate, wherein the lens module has a module body and at least one lens formed in the module body and corresponding to the at least one LED, And at least one reflecting portion protruded downward from the lower surface of the module body is provided to reflect at least a part of the light toward a lower side of the module body within a predetermined forward and backward angular range.

Wherein each of the one or more reflectors includes at least a portion of the light traveling toward the rear end of the module body relative to an imaginary line perpendicularly traversing the module body at a location where the LEDs are disposed, As shown in Fig.

Further, the refractive index of each of the at least one reflection portion is greater than the refractive index of air, and each of the at least one reflection portion is arranged to project at least a part of light traveling toward the rear of the module body out of the predetermined forward- In a direction in which the light is reflected.

In particular, each of the one or more reflectors is formed in a polygonal shape extending in a width direction of the module body, and is provided corresponding to each of the at least one lens, And a first reflection surface for reflecting the light irradiated toward the light source within the predetermined forward and backward angular range.

Further, each of the one or more reflective portions may include an introducing surface formed to introduce light irradiated from the corresponding LED toward the reflective portion into the reflective portion; And a first refracting surface adjacent to the introducing surface, the refracting surface being formed to refract light reflected by the first reflecting surface and introduced into the introducing surface.

At this time, the first refracting surface may be formed to refract at least a part of the light reflected by the first reflecting surface within the set forward and backward angular range.

Further, each of the at least one reflection portion is formed to refract at least a part of the light reflected by the first reflection surface into the set forward and backward angular range, and is positioned between the first refraction surface and the first reflection surface And a refraction angle of the light reflected by the first reflection surface may be smaller in the second refraction surface than in the first refraction surface.

Also, the first reflection surface may be formed to be inclined at 110 to 120 degrees with respect to the lower surface of the module body toward the rear of the module body.

The reflector may be disposed behind each of the at least one lens at a distance from the at least one lens in the module body.

The reflector may be integrally formed with the module body.

Meanwhile, the module body may have at least one incision portion formed at the rear of each of the at least one lens corresponding to the at least one lens, and the at least one incision portion may be formed to extend in the width direction of the module body.

At this time, a part of the reflection part can be located in the cutout part.

Specifically, the upper end of the reflective portion may be positioned within the cutout portion, and the width of the upper end of the reflective portion may be the same as the width of the cutout portion.

Meanwhile, the module body may further include a second reflecting surface, and the second reflecting surface may be formed to be inclined from the lower surface of the module body at the front end of the module body toward the rear end of the module body from the upper surface thereof .

At this time, the second reflection surface may be formed over the entire width direction of the module body.

Also, the angle between the second reflecting surface and the upper surface of the module body may be between 145 and 155 degrees.

The illumination device according to an embodiment of the present invention further includes a case having the light emitting module, the power supply unit, and the lens module, and the case includes an upper case and a lower case coupled to each other, An installation hole for installing a lighting device on a support column is formed, and an opening corresponding to the light emitting module may be formed in the lower case.

According to the present invention, it is possible to provide an illumination device capable of reducing harmful backlight directed toward a house located near a lighting device.

Further, according to the present invention, it is possible to provide a lighting apparatus capable of preventing light pollution to a house or a roadside tree located near a lighting apparatus (that is, behind the lighting apparatus) through harmful backlight reduction of the lighting apparatus (street lamp) .

Further, according to the present invention, it is possible to prevent a problem of sleeping disorder that may occur in a person who lives in a house located near a lighting apparatus (i.e., behind the lighting apparatus) due to a harmful backlight of the lighting apparatus.

Further, according to the present invention, it is possible to provide an illumination device capable of increasing the light efficiency or optical density of light irradiated toward the road below the illuminating device.

Figure 1 shows a typical example of a lighting device (i.e. street lamp) formed to illuminate a conventional road.
2 is an exploded perspective view of a lighting apparatus according to an embodiment of the present invention.
FIG. 3 (a) is a bottom perspective view of a lens module according to an embodiment of the present invention, and FIG. 3 (b) is a plan perspective view of the lens module.
Fig. 4 is a cross-sectional view of the lens module along the DD direction in Fig. 3 (a). Fig.
5 is a schematic view showing a state in which light is irradiated through a single lens provided in a conventional lens module.
6 is a schematic view showing a state in which light is irradiated through one lens included in a lens module according to an embodiment of the present invention.

Hereinafter, a lighting apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

In addition, the same or corresponding components are denoted by the same reference numerals regardless of the reference numerals, and redundant description thereof will be omitted. For convenience of explanation, the size and shape of each constituent member shown may be exaggerated or reduced have.

On the other hand, terms including an ordinal number such as a first or a second may be used to describe various elements, but the constituent elements are not limited by the terms, and the terms may refer to a constituent element from another constituent element It is used only for the purpose of discrimination.

2 is an exploded perspective view of a lighting apparatus according to an embodiment of the present invention. For convenience of explanation, the X axis direction is defined as a forward / backward direction, the Y axis direction is defined as a vertical direction (or height direction), and the Z axis direction is defined as a width direction.

2, a lighting apparatus 10 according to an embodiment of the present invention includes a light emitting module 100, a light emitting module 100 disposed below the light emitting module 100, One or more lens modules 200 formed to determine the size of the light emitting module 100, for example, a wide range of the light emitting module 100, and a power supply unit 315 configured to supply power to the light emitting module 100.

The light emitting module 100 may include a substrate 110 and one or more light emitting diodes 120 (hereinafter also referred to as LEDs) mounted on the substrate 110.

The lens module 200 may be disposed on the lower side of the substrate 110. In addition, the lens module 200 may be formed to refract or reflect light emitted from the LED 120.

The lens module 200 may include a module body 210 and one or more lenses 220 formed on the module body 210 and corresponding to the one or more LEDs 120.

In the illustrated embodiment, a plurality of LEDs 120 are mounted on one substrate 110 formed in a rectangular shape, but a plurality of LEDs 120 may be mounted on a substrate 110 divided into a plurality of substrates.

That is, a plurality of (e.g., six) lens modules 200 may be provided. In addition, each of the lens modules 200 may include four lenses 220. At this time, the four lenses 220 may be spaced apart from each other at the same angular distance with respect to the center of the module body 210.

At this time, the plurality of lenses 220 provided in the plurality of lens modules 200 may be arranged corresponding to the plurality of LEDs 120 mounted on the substrate 110. That is, the number of the lenses 220 and the number of the LEDs 120 may be the same.

The illumination device 10 may further include a case 300 in which the light emitting module 100, the lens module 200, and the power supply unit 315 are embedded.

The case 300 may include an upper case 310 and a lower case 320 coupled to each other

At this time, the upper case 310 may be provided with an installation hole 311 for installing the lighting device 10 in a mounting pillar (according to the related art).

The lighting device 10 may be installed on the installation pole through the installation hole 311. That is, the lighting apparatus 10 according to the embodiment of the present invention can be used for a streetlight formed to illuminate a road or a ledge, as described through the prior art.

In other words, the lighting apparatus 10 may be provided at an upper end of a mounting post having a predetermined height, and may be formed to irradiate light downward toward the road or the ledge.

The lower case 320 may have an opening 321 corresponding to the light emitting module 100.

The illumination device 10 according to the embodiment of the present invention is disposed along the circumferential direction of the light emitting module 100 from below the light emitting module 100 to reflect light emitted from the light emitting module 100 A transparent member 500 (for example, a transparent glass) disposed below the reflective member 400 and an outer circumferential surface of the transparent member 500 and a lower surface of the lower case 320 And a sealing member 600 sealing between the inner peripheries of the openings 321 formed.

The reflective member 400, the transparent member 500, and the sealing member 600 are well-known structures, and a detailed description thereof will be omitted.

Meanwhile, a part of the light irradiated from the LED 120 and passing through the lens module 200 may form a harmful backlight directed to the rear of the illumination device 10. [ Such a harmful backlight can cause light pollution.

Therefore, the lens module 200 included in the illumination device 10 according to the embodiment of the present invention may be provided with one or more reflective surfaces for reducing the harmful backlight and increasing the light efficiency. Hereinafter, the configuration of the one or more reflective surfaces will be described in detail with reference to the other drawings.

FIG. 3 (a) is a bottom perspective view of a lens module according to an embodiment of the present invention, and FIG. 3 (b) is a plan perspective view of the lens module. 4 is a cross-sectional view of the lens module along the direction D-D in Fig. 3 (a).

In the following description, one lens module 200 is used as a reference, but it is apparent from the above description that a plurality of the lens modules 200 may be provided in the illumination device according to the embodiment of the present invention.

3 to 4, the lens module 200 may include a module body 210 and a plurality of lenses 220 formed on the module body 210.

The module body 210 may have a predetermined thickness and may be formed as a rectangular or square plate.

A coupling hole 211 for coupling the module body 210 to the substrate 110 and the upper case 310 through a coupling member (not shown) is formed at the center of the module body 210 .

The plurality of lenses 220 may be formed on the module body 210 at a predetermined angle with respect to the center of the module body 210 (i.e., with reference to the fastening holes 211).

For example, four lenses 220 may be formed on the module body 210 at the same distance from each other with reference to the fastening holes 211 of the module body 210.

Referring to FIG. 3A, the plurality of lenses 220 may protrude downward from one side (lower surface) of the module body 210.

3 (b), the plurality of lenses 220 may be concave downward from the other side (that is, the upper surface) of the module body 210.

4, at least a part of the LED 120 corresponds to a space defined by the lens 220 at the upper portion of the module body 210, As shown in FIG.

For example, the LED 120 may be arranged such that the lower end 121 of the LED 120 is inserted into the space 221 defined by the lens 220 at the upper portion of the module body 210 .

Meanwhile, the module body 210 may include at least one reflector 230 for reflecting at least a part of the light emitted from the LED 120.

The at least one reflector 230 may be formed to totally reflect at least a part of the light emitted from the LED 120 toward a downward direction of the module body 210 in a predetermined forward and backward angular range.

In addition, the at least one reflector 230 may protrude downward from the module body.

Each of the one or more reflectors 230 may be disposed behind the at least one lens 220 at a predetermined distance from the at least one lens 220 at the module body 210.

For example, the module body 210 may include one or more lenses 220 corresponding to each of the one or more reflective portions 230.

In addition, the at least one reflector 230 may be integrally formed with the module body 210. However, it is not excluded that the reflector 230 is manufactured separately from the module body 210 and is coupled to the module body 210.

Each of the one or more reflecting portions 230 may be formed on a side of the module body 210 with respect to an imaginary line V perpendicularly crossing the module body 210 at a position where the LED 120 is disposed. May be formed to totally reflect at least part of the light traveling toward the rear end portion 200 " in the direction toward the imaginary line (V).

That is, the virtual line V may be formed so as to cross the module body 210 vertically (i.e., vertically) at a position on the module body 210 on which each of the one or more LEDs 120 is disposed have.

In this case, when one module body 210 and at least one lens 220 are provided, one or more LEDs 120 corresponding to each of the at least one lens 220 may be disposed above the module body 210.

Accordingly, if more than one lens 220 is provided in one module body 210, the virtual line V may be formed in correspondence with one or more lenses 220.

Each of the one or more reflecting portions 230 may include at least a portion of the light traveling toward the rear end of the module body 210 with respect to the corresponding imaginary line V, As shown in Fig.

The refractive index of the reflective portion 230 may be greater than the refractive index of the air to totally reflect light toward the reflective portion 230.

In addition, each of the one or more reflecting portions 230 may be configured to totally reflect at least a part of the light traveling toward the rear of the module body 210 in the direction toward the imaginary line (V) out of the predetermined forward and backward angular range .

The predetermined forward and backward angular range is defined by a rear set angle a1 toward the rear of the module body 210 with respect to the imaginary line V shown in FIG. And a front setting angle a2 toward the front of the vehicle.

On the other hand, the angular range adjacent to the rear set angle a1 as the angular range toward the rear of the module body 210 with respect to the virtual line V can be defined as the harmful backlit footprint a3.

That is, the angle of incidence of the light emitted from one LED 120 may include a rear setting angle a1, a front setting angle a2, and a harmful backlighting idea a3.

In other words, as shown in FIG. 4, the initial angle of incidence of the light emitted from one LED 120 is in a range of the sum of the rear set angle a1, the front set angle a2, and the harmful backlight outlook a3 .

At this time, in order to reduce or prevent the generation of the harmful backlight, the rear setting angle a1 may be 30 degrees or less. For example, the rear setting angle a1 may be 25 ° to 30 °.

At least a part of the light irradiated from the LED 120 and traveling in the range of the harmful backlighting idea a3 is reflected by the reflection portion 230 toward the virtual line V at the predetermined forward and backward angle Lt; / RTI >

Preferably, all the light emitted from the LED 120 and traveling within the range of the harmful backlighting idea a3 is reflected by the reflective portion 230 toward the imaginary line V by the predetermined forward / Lt; / RTI >

Therefore, the unnecessary harmful backlight that may be generated from the illumination device 10 can be reduced by the reflective portion 230. Further, the harmful backlight of the lighting apparatus 10 can be changed in its progress path so as to increase the light efficiency or the light density within the predetermined forward and backward angular range by the reflector 230.

Here, the fact that the light efficiency (or optical density) of the lighting apparatus 10 is increased means that light can be concentrated on the road or the part where the light is to be irradiated by the lighting apparatus 10 used for the streetlight it means.

Each of the one or more reflecting portions 230 provided in the module body 210 may be formed in a polygonal shape extending in the width direction of the module body 210. That is, each of the at least one reflection part 230 may be formed in the form of a prism extending in the width direction of the module body 210.

Each of the one or more reflectors 230 may correspond to one or more lenses 220 or one or more LEDs 120 provided on the module body 210.

For example, each of the one or more reflection portions 230 may be provided to correspond to the plurality of lenses 220 or the plurality of LEDs 120. [

In the illustrated embodiment, one lens module 210 may be provided with four lenses 220 and two reflectors 230.

At this time, the two reflectors 230 and the four lenses 220 may be arranged to correspond to each other at a ratio of 1: 2. That is, each of the two reflectors 230 may be provided to correspond to the two lenses 220.

3 (a), a plurality of lenses 220 provided in one module body 210 are arranged at a front portion of the module body 210 with respect to a longitudinal center of the module body 210, (E.g., two) first lenses 220-1 arranged side by side in the width direction of the first lens 220-1.

The plurality of lenses 220 provided in the one module body 210 are arranged in the width direction of the module body 210 at the rear side relative to the center of the module body 210 in the longitudinal direction, (For example, two) second lenses 220-2.

For example, a plurality of first lenses 220-1 may be arranged in the width direction of the module body 210 in the front part of the module body 210, 220-2 may be arranged side by side in the width direction of the module body 210 at the rear portion with respect to the center of the module body 210 in the longitudinal direction.

The reflector 230 provided in the one module body 210 includes a first reflector 230-1 disposed at a front portion of the module body 210 with respect to the center of the module body 210, And a second reflector 230-2 disposed at a rear portion of the first reflector 210 with respect to the front-rear direction center of the second reflector 230-2.

The first reflector 230-1 may be disposed behind the first lens 220-1 and the second reflector 230-2 may be disposed behind the second lens 220-2. As shown in FIG. In particular, the second reflector 230-2 may be disposed at a rear end of the module body 210. [

Accordingly, the first reflector 230-1 may be formed to totally reflect the light emitted from the LED 120 corresponding to the first lens 220-1, and the second reflector 230- 2 may be formed so as to totally reflect the light emitted from the LED 120 corresponding to the second lens 220-2.

Each of the one or more reflecting portions 230 may include a first reflecting surface 231 for reflecting the light emitted from the corresponding LED 120 toward the reflecting portion 230 in the predetermined forward and backward angle range .

The first reflecting surface 231 is formed so as to totally reflect the light directed toward the first reflecting surface 231 through a difference in refractive index between the reflecting portion 230 and the air behind the first reflecting surface 231 . That is, the refractive index of the reflective portion 230 may be greater than the refractive index of the air.

The first reflection surface 231 may be formed to be inclined at a predetermined angle toward the rear of the module body 210 with respect to the virtual line (V).

For example, the lower surface of the module body 210 is shown in FIG. 3A, and the upper surface of the module body 210 is shown in FIG. 3B. In FIG. 4, reference numeral 218 denotes a lower surface of the module body 210, and reference numeral 219 denotes an upper surface of the module body 210.

At this time, the first reflecting surface 231 may be formed to be inclined at 110 ° to 120 ° with respect to the lower surface 218 of the module body 210 toward the rear of the module body 210.

The first reflection surface 231 may be formed to be inclined at 115 degrees with respect to the lower surface 218 of the module body 210 toward the rear of the module body 210. [

The optimum value of the angle (d) between the first reflecting surface 231 and the lower surface 218 of the module body 210 is a value obtained through experiments, Which is a value capable of maximizing the total reflection of light through the light source 235.

That is, when the angle d between the first reflection surface 231 and the lower surface 218 of the module body 210 becomes 130 ° to 140 °, Can be totally reflected by the first reflecting surface 231. [0157]

Each of the at least one reflection part 230 includes an introduction surface 232 for introducing the light emitted from the LED 120 toward the reflection part 230 into the reflection part 230, And a first refracting surface 233 formed to refract light reflected by the first refracting surface 231.

The introduction surface 232 may be formed to introduce light irradiated from the LED 120 corresponding to the reflection portion 230 toward the reflection portion 230 into the reflection portion 230.

That is, the introduction surface 232 may be formed to introduce light proceeding within the range of the harmful backlight outlook a3 of the light emitted from the LED 120 into the reflection portion 230.

That is, the introduction surface 232 may be a surface closest to the corresponding LED 120 among the surfaces of the reflective portion 230.

At this time, the introduction surface 232 is formed with a predetermined angle e (hereinafter referred to as a "second angle") with respect to the lower surface of the module body 210 toward the front of the module body 210 with respect to the imaginary line V, May be formed so as to be inclined.

The first refracting surface 233 may be provided adjacent to the introducing surface 232. That is, the first refracting surface 233 may be formed to be inclined toward the rear of the module body 210 at a predetermined angle (f) (hereinafter also referred to as "third angle") at the lower end of the introducing surface 232 have.

The first refracting surface 233 may be formed to refract at least a part of the light reflected by the first reflecting surface 231 by being introduced into the introducing surface 232.

That is, the light introduced into the entrance surface 232 and totally reflected by the first reflecting surface 231 may be refracted in the process of passing through the first refracting surface 233.

In other words, the first refracting surface 233 may be formed to refract the light reflected by the first reflecting surface 231 into the predetermined forward and backward angular range a1 + a2.

Even if the light totally reflected by the first reflecting surface 231 is refracted through the first refracting surface 233, the light refracted after the total reflection enters the predetermined forward and backward angular range a1 + a2 and the virtual line V As shown in Fig.

Therefore, the light emitted from the LED 120 and passing through the entrance surface 232, the first reflecting surface 231, and the first refracting surface 233 is incident on the predetermined forward and backward angular range a1 + a2, The light efficiency can be increased at the same time as the harmful backlight reduction of the illumination device 10 is achieved.

Each of the one or more reflection units 230 may further include a second refracting surface 234 adjacent to the first refracting surface 233.

That is, the second refracting surface 234 may be positioned between the first refracting surface 233 and the first reflecting surface 231.

Also, the first refracting surface 233 may be positioned between the introduction surface 232 and the second refracting surface 234.

The second refracting surface 234 may be formed to be inclined toward the rear of the module body 210 at a predetermined angle g (hereinafter referred to as "fourth angle") at the lower end of the first refracting surface 233 .

The second refracting surface 234 is formed to be inclined toward the front of the module body 210 at a predetermined angle h (hereinafter also referred to as "fifth angle") at the lower end of the first reflecting surface 231 .

That is, the upper end of the second refracting surface 234 is connected to the lower end of the first refracting surface 233 by the fourth angle g, and the lower end of the second refracting surface 234 is connected to the first inclined surface 231, And the fifth angle (h).

Wherein the first angle (d), the third angle (f), and the fourth angle (g) are formed at obtuse angles and the second angle (e) and the fifth angle .

In addition, the first to fourth angles (d) to (h) may be formed at different angles.

For example, the first angle (d) may be between 110 ° and 120 °. Preferably, the first angle (d) may be 115 [deg.].

The second refracting surface 234 may be formed to refract at least a part of the light reflected by the first reflecting surface 231 by the introduction surface 232.

In other words, the second refracting surface 234 may be formed to refract at least a part of the light reflected by the first reflecting surface 231 into the predetermined forward and backward angular range a1 + a2.

For example, a part of light reflected by the first reflecting surface 231 is introduced into the entrance surface 232 through the first refracting surface 233 and reflected by the first reflecting surface 231 The remainder of the light may be refracted through the second refracting surface 234.

Specifically, the light reflected from the upper end of the first reflecting surface 231 and the vertical central portion 231 'of the first reflecting surface 231, among the light reflected from the first reflecting surface 231, And can proceed toward the first refracting surface 233.

The light reflected from the central portion 231 'of the first reflecting surface 231 in the vertical direction and the lower end of the first reflecting surface 231 may be reflected by the first reflecting surface 231, And can proceed toward the second refracting surface 234.

Even if the light totally reflected by the first reflecting surface 231 is refracted through the first refracting surface 233 and the second refracting surface 234, the light refracted after the total reflection reaches the predetermined forward and backward angular range a1 + a2 ) And in a direction toward the imaginary line (V).

Therefore, the light emitted from the LED 120 and passing through the entrance surface 232, the first reflecting surface 231, and the second refracting surface 234 is incident on the predetermined forward and backward angular range a1 + a2, The light efficiency can be increased at the same time as the harmful backlight reduction of the illumination device 10 is achieved.

3 (a) and 3 (b), the module body 210 may include one or more cutouts 216. Referring to FIGS. The at least one cutout 216 may correspond to one or more lenses 220 of the module body 210.

Specifically, the at least one cutout 216 may be formed at the rear of the corresponding lens 220 in the module body 210, respectively.

In the illustrated embodiment, the one or more cutouts 216 may be provided corresponding to the first lens 220-1 and two corresponding to the second lens 220-2, respectively. That is, four module cutouts 216 may be formed in one module body 210.

At this time, two cut-out portions 216 formed at the rear portion of the module body 210 with respect to the front-rear direction center may be provided at the rear end of the module body 210.

The one or more cutouts 216 prevent the light emitted from the LED 120 from traveling to the rear end of the module body 210 through the interior of the module body 210.

That is, a part of the light emitted from the LED 120 may be totally reflected inside the module body 210 and proceed toward the rear end of the module body 210. In this way, the light propagating toward the rear end of the module body 210 inside the module body 210 may generate a harmful backlight, which may lower the light efficiency of the illumination device 10. [

The at least one cutout 216 formed at a predetermined distance from the rear of the lens 220 in the module body 210 is irradiated from the LED 120 and is irradiated from the module body 210 210 from moving toward the rear end.

Each of the one or more cutouts 216 may be formed to extend in the width direction of the module body 210.

The reflection portion 230 may be formed to protrude downward from the module body 210 at a position corresponding to the cut-out portion 216.

In the illustrated embodiment, two reflectors 230 may be provided on one module body 210.

One of the two reflectors 230 is provided at a position corresponding to the two cutouts 216 formed in the front portion of the module body 210 with respect to the longitudinal center of the module body 210, And may be provided at positions corresponding to the two cut-out portions 216 formed in the rear portion with respect to the center in the forward and backward direction.

A portion of the reflective portion 230 may be disposed in the cutout portion 216. For example, the upper end of the reflector 230 may be positioned within the cutout 216.

At this time, the width of the upper end of the reflective portion 230 located in the cutout portion 216 may be the same as the width of the cutout portion 216.

Specifically, the first reflection surface 231 of the reflection portion 230 and the upper end of the introduction surface 233 may be disposed in the cut-out portion 216.

That is, the first reflection surface 231 and the upper end of the introduction surface 233 may be positioned in the cut-out portion 216. The first reflection surface 231 and the lower end of the introduction surface 233 may be spaced downward from the lower surface of the module body 210.

In addition, the upper ends of the first reflection surface 231 and the introduction surface 233 may be formed in line contact. A line where the upper end of the first reflecting surface 231 and the upper end of the introduction surface 233 meet may be flush with the upper surface 219 of the module body 210.

Accordingly, when a portion of the light emitted from the LED 120 advances into the incision 216, at least a portion of the light traveling into the incision 216 is introduced into the incidence surface 233, And can be totally reflected toward the lower side of the module body 210 by the reflecting surface 231. [

Meanwhile, the module body 210 may further include a second reflecting surface 215. The second reflective surface 215 may be formed at the front end 210 'of the module body 210.

The second reflecting surface 215 may be inclined from the lower surface 218 of the module body 210 to the upper surface 219 toward the center of the module body 210 in the longitudinal direction of the module body 210.

In other words, the second reflecting surface 215 may be formed to be inclined from the lower surface 219 of the module body 210 to the upper surface 218 of the module body 210 toward the center of the module body 210 have.

In the illustrated embodiment, the second reflective surface 215 may be formed at the front end 210 'of the module body 210.

At this time, the second reflection surface 215 may be formed to be inclined in a direction opposite to the first reflection surface 231.

Also, the second reflecting surface 215 may be formed to extend over the entire width of the module body 210.

That is, the second reflecting surface 215 may be formed over the entire width of the module body 210.

The second reflecting surface 215 may be formed to totally reflect the light that is emitted from the LED 120 and travels to the front end of the module body 210 through the inside of the module body 210, have.

In order to totally reflect the light, the module body 210 is preferably formed such that the refractive index of the module body 210 is larger than the refractive index of the air.

Therefore, the light efficiency (or optical density) of the illumination device 10 can be improved by the second reflecting surface 215. [

In addition, the angle (i) between the second reflecting surface 215 and the upper surface 219 of the module body 210 is preferably 145 ° to 155 ° (see FIG. 4).

The angle (i) between the second reflecting surface 215 and the upper surface 219 of the module body 210 may be 150 °.

The optimum value of the angle (i) between the second reflecting surface 215 and the upper surface 219 of the module body 210 is a value obtained through experiments, and the total reflection of light through the second reflecting surface 215 It corresponds to a value that can be maximized.

2, the illumination device 10 according to the embodiment of the present invention may include a plurality of lens modules 200, and the second reflecting surface 215 may include a plurality of lens modules 200, (Not shown).

Hereinafter, with reference to the other drawings, it is assumed that the total reflection of light through the first reflection surface 231 is not used and the total reflection of light through the first reflection surface 231 is used, LED will be described and compared.

5 is a schematic view showing a state in which light is irradiated through a single lens provided in a conventional lens module.

5 illustrates a path through which the light emitted from the LED 120 travels when the lens module 200 does not include the first reflecting surface 231. In other words, FIG.

For convenience of explanation, the path of the light will be described with reference to the light emitted from one LED 120.

The light irradiated from the LED 120 and directed to the lower side of the lens module 200 travels in the entire angular range a1 + a2 + a3 of the lens module 200 in the front-rear direction (i.e., the X-axis direction).

The total angular range a1 + a2 + a3 is set such that the total angular range a1 + a2 + a3 is set to be a distance from the rear of the lens module 200 to the rear of the lens module 200 with respect to the imaginary line V vertically penetrating the module body 210 at the position of the LED 120 A rear setting angle a1, a front setting angle a2 directed toward the front of the lens module 200 and a harmful backlit gazing a3 adjacent to the rear setting angle a1.

The harmful backlit footprint a3 may be adjacent to the rearward facing side of the lens module 200 at the rear setting angle a1.

In addition, the harmful backlight footprint a3 may cause light pollution to a house or street tree near the rear of the lighting apparatus 10. [

Further, although not shown, a part of the light emitted from the LED 120 may travel toward the front end or the rear end of the module body 210 in the module body 210.

Light traveling toward the front end or the rear end of the module body 210 may deviate from an area to be illuminated by the illuminating device 10 (e.g., road and delivery).

Therefore, the light traveling toward the front end or the rear end of the module body 210 in the module body 210 may cause a decrease in the light efficiency (or optical density) of the illumination device 10.

In addition, the light propagating toward the front end or the rear end of the module body 210 in the module body 210 may damage the light pollution in a house or a roadside near the front or rear of the lighting device 10.

Particularly, light propagating toward the rear end of the module body 210 in the module body 210 may increase the generation of unnecessary harmful backlight.

Hereinafter, with reference to other drawings, the principle of preventing the generation of harmful backlight by the lens module 200 according to the embodiment of the present invention and increasing the light efficiency will be described.

FIG. 6 is a schematic view showing a state in which light is irradiated through one lens included in a lens module according to an embodiment of the present invention.

6 illustrates a path through which the light emitted from the LED 120 advances when the lens module 200 includes the first reflecting surface 231. In other words, FIG.

For convenience of explanation, the path of light will be described with reference to one LED 120 and a reflector 230 corresponding to the LED 120. [

The light irradiated from the LED 120 and directed to the lower side of the lens module 200 can proceed to the entire angular range a1 + a2 + a3 of the lens module 200 in the front-rear direction (i.e., the X-axis direction).

5, the overall angular range a1 + a2 + a3 is set to be a distance from the center of the module body 210 to the center of the module body 210 with respect to the imaginary line V passing vertically through the module body 210, A rear setting angle a1 toward the rear of the lens module 200, a front setting angle a2 toward the front of the lens module 200 and a harmful backlit footprint a3 adjacent to the rear setting angle a1 .

At this time, the light proceeding within the range of the harmful backlight footprint a3 may be totally reflected by the reflector 230 provided on the module body 210 at the rear of the lens 220. [

The light totally reflected by the reflection unit 230 may proceed within a predetermined anteroposterior angle range a1 + a2.

That is, the light totally reflected by the reflection unit 230 may travel toward the imaginary line V that crosses the center of the LED 120 in the up and down direction.

The predetermined forward and backward angular range (a1 + a2) is a range determined through experiments so as to prevent or reduce the occurrence of harmful backlight. In particular, the value of the rear set angle a1 is related to the occurrence of the harmful backlight, and the rear set angle a1 is preferably 30 degrees or less.

It is possible to prevent or reduce the generation of unnecessary harmful backlight by the reflector 230 and reduce the light efficiency or optical density based on the area to be illuminated by the illuminating device 10 Can be increased.

Further, although not shown, a part of the light emitted from the LED 120 may travel toward the front end or the rear end of the module body 210 in the module body 210.

The light propagating toward the front end of the module body 210 in the module body 210 passes through the second reflection surface 215 provided at the front end of the module body 210, It can be totally reflected downward.

The light propagating toward the rear end of the module body 210 in the module body 210 is firstly blocked by the cutout section 216 and the light emitted from the module body 210 through the first reflection surface 231, May be totally reflected downward of the substrate 210.

Therefore, the harmful backlight of the illumination device 10 can be prevented by the cutout 216, the first reflecting surface 231 and the second reflecting surface 215, and at the same time, the light efficiency or optical density can be improved .

The foregoing description of the preferred embodiments of the present invention has been presented for purposes of illustration and various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention, And additions should be considered as falling within the scope of the following claims.

10 Lighting device 100 Light emitting module
110 Substrate 120 Light Emitting Diode (LED)
200 Lens module 210 Module body
215 second reflecting surface 216 incision section
220 lens 230 reflector
231 1st reflection plane 300 case

Claims (17)

A light emitting module including a substrate and at least one LED mounted on the substrate;
At least one lens module disposed below the substrate and configured to refract or reflect light emitted from the LED; And
And a power supply unit electrically connected to the substrate,
The lens module having a module body and at least one lens formed in the module body and corresponding to the at least one LED,
The module body is provided with at least one reflecting portion protruding downward from the lower surface of the module body in order to reflect at least a part of the light irradiated from the LED toward the downward direction of the module body in a predetermined forward and backward angular range . The method according to claim 1,
Wherein each of the one or more reflective portions comprises:
And at least a part of the light traveling toward the rear end of the module body is totally reflected in a direction toward the imaginary line with respect to an imaginary line perpendicularly crossing the module body at the position where the LED is disposed Lt; / RTI > 3. The method of claim 2,
Wherein the refractive index of each of the one or more reflective portions is greater than the refractive index of air,
Wherein each of the at least one reflecting portion is formed to totally reflect at least a part of light traveling toward the rear of the module body in a direction toward the imaginary line out of the predetermined forward and backward angular range. The method according to claim 1,
Wherein each of the at least one reflection part is formed in a polygonal shape extending in the width direction of the module body and is provided corresponding to each of the at least one lens,
Wherein each of the at least one reflecting portion includes a first reflecting surface for reflecting the light emitted from the corresponding LED toward the reflecting portion within the predetermined forward and backward angular range. 5. The method of claim 4,
Wherein each of the one or more reflective portions comprises:
An entrance surface formed to introduce light irradiated from the corresponding LED toward the reflection section into the reflection section; And
Further comprising a first refracting surface adjacent to the introducing surface, the refracting surface being formed to refract light reflected from the first reflecting surface. 6. The method of claim 5,
Wherein the first refracting surface is formed to refract at least a part of the light reflected by the first reflecting surface within the set forward and backward angular range. 6. The method of claim 5,
Wherein each of the one or more reflective portions comprises:
Further comprising a second refracting surface formed between the first refracting surface and the first refracting surface, the second refracting surface being formed to refract at least a part of the light reflected from the first refracting surface into the set forward and backward angular range,
Wherein a refraction angle of the light reflected by the first reflection surface is smaller at the second refraction surface than at the first refraction surface. 5. The method of claim 4,
Wherein the first reflecting surface is formed to be inclined at 110 to 120 degrees with respect to a lower surface of the module body toward the rear of the module body. 5. The method of claim 4,
Wherein the reflector is spaced a predetermined distance from the at least one lens in the module body and is disposed behind each of the at least one lens. 5. The method of claim 4,
Wherein the reflector is formed integrally with the module body. 5. The method of claim 4,
Wherein the module body is provided with at least one incision portion corresponding to each of the at least one lens and formed at the rear of each of the at least one lens,
Wherein the at least one cut-out portion is formed to extend in the width direction of the module body. 12. The method of claim 11,
And a part of the reflection part is located in the cut-out part. 13. The method of claim 12,
An upper end of the reflection portion is positioned in the cutout portion,
Wherein a width of an upper end of the reflective portion is equal to a width of the cutout portion. 5. The method of claim 4,
Wherein the module body further comprises a second reflecting surface,
Wherein the second reflecting surface is formed to be inclined from the lower surface of the module body to the upper surface of the module body at the front end of the module body toward the rear end of the module body. 15. The method of claim 14,
And the second reflecting surface is formed over the entire width direction of the module body. 15. The method of claim 14,
And an angle between the second reflecting surface and the upper surface of the module body is between 145 [deg.] And 155 [deg.]. The method according to claim 1,
Further comprising a case in which the light emitting module, the power supply unit, and the lens module are embedded,
The case has an upper case and a lower case coupled to each other,
In the upper case, an installation hole for installing a lighting device is formed on a snow pillar,
Wherein the lower case has an opening corresponding to the light emitting module.

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