KR101714441B1 - Lighting apparatus - Google Patents

Abstract

The present invention relates to a lighting apparatus, and more particularly, to a lighting apparatus comprising: a light emitting unit including at least one substrate module and a plurality of LED arrays installed in the substrate module; At least one lens module detachably mounted to the light emitting unit; A heat sink provided with the light emitting unit; A first housing provided at one longitudinal end of the heat sink; A second housing provided at the other longitudinal end of the heat sink; And at least one power module provided in the first housing for supplying power to the light emitting unit.

Description

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting apparatus, and more particularly, to a lighting apparatus which can realize various sizes and various light distribution performance by modularized components and can improve heat radiation performance.

In general, an LED is a semiconductor device that emits light when a voltage is applied in a forward direction, has a long lifetime, low power consumption, has electrical, optical, and physical characteristics suitable for mass production, and is rapidly replacing incandescent bulbs and fluorescent lamps. In addition, LEDs are quickly applied to outdoor lighting such as street lamps, security lamps, parks, and security lamps.

Particularly, the luminaire is installed in the form of hanging on a pillar member, and it should be possible to investigate the angle of light according to the surrounding environment in an optimal state.

On the other hand, the LED has a small light distribution angle and a strong directivity. Therefore, in order to realize a constant angle of incidence (directional angle), the LED illumination device includes a lens unit for adjusting the direction of light emitted from the LED.

In particular, when lighting is provided on the roadway and on the road, such as a streetlight, the lens units must be individually designed and manufactured to optimize for various road lighting environments.

On the other hand, when the streetlight is installed incorrectly, the light distribution angle with respect to the road surface or the installation surface is not maintained properly, so that there arises a problem that light is irradiated to an area where illumination is unnecessary or illuminance of an area where illumination is required is reduced.

Further, in the LED lighting apparatus, a structure is required to effectively dissipate the heat generated from the light emitting diodes (LEDs). If the heat generated by the LED can not be diverted to the outside, the efficiency of the lighting apparatus is lowered.

An object of the present invention is to provide a lighting device capable of realizing light distribution optimized for various outdoor lighting environments.

Another object of the present invention is to provide a lighting device capable of realizing individual light distribution for each specific area of a road or a certain area of a road.

Another object of the present invention is to provide a lighting apparatus which can realize various light distribution through combination of lenses having different light distribution curves.

An object of the present invention is to provide a lighting device capable of improving heat dissipation performance.

Another object of the present invention is to provide a lighting apparatus capable of continuously changing convective heat exchange characteristics of outside air in the process of passing outside air through a heat sink.

It is another object of the present invention to provide a lighting device capable of guiding the flow of outside air through a Coanda effect.

According to an aspect of the present invention, there is provided a light emitting device comprising: a light emitting unit including at least one substrate module, and a plurality of LED arrays installed in the substrate module; At least one lens module detachably mounted to the light emitting unit; A heat sink provided with the light emitting unit; A first housing provided at one longitudinal end of the heat sink; A second housing provided at the other longitudinal end of the heat sink; And at least one power module provided in the first housing for supplying power to the light emitting unit.

In this case, the light emitting unit may include a plurality of substrate modules, and each of the plurality of substrate modules may include a plurality of LED arrays.

In addition, a plurality of lens modules may be detachably mounted on the substrate module, and each of the plurality of lens modules may be disposed to surround a corresponding one of the plurality of LED arrays installed in the substrate module.

In addition, a plurality of lens modules may be arranged along the longitudinal direction of the substrate module at a central portion of each of the plurality of lens modules, and a plurality of lens modules may be arranged along the longitudinal direction of the substrate module.

The LED array may include a plurality of LEDs. The lens module may include a plurality of lenses. The plurality of lenses of the lens module may include a plurality of LEDs, And may be provided along the circumferential direction with respect to the center.

The plurality of lens modules may include at least one first lens module having a first light distribution characteristic and at least one second lens module having a second light distribution characteristic different from the first light distribution characteristic.

In addition, a plurality of connectors for electrically connecting the substrate module and the power module may be provided on a side surface of each of the plurality of substrate modules.

According to an embodiment of the present invention, the lighting device further includes a side substrate disposed at one longitudinal end of the plurality of substrate modules, and one end of the plurality of connectors is connected to the side substrate And the other end of the plurality of connectors may be detachably connected to one longitudinal end portion of the plurality of substrate modules.

Also, the number of the power supply modules may be determined according to at least one of the number of the substrate modules and the number of the LED arrays.

The first housing may include an upper case and a lower case coupled to the upper case, and one longitudinal end of the upper case may be hinged to one longitudinal end of the lower case.

In addition, a fixing member is provided on both widthwise sides of the other longitudinal direction end of one of the upper case and the lower case, and on both widthwise sides of the other longitudinal direction end of the other of the upper case and the lower case, The protrusion may be provided at a position corresponding to the fixing member.

Further, one end of the fixing member is hinged to one of the upper case and the lower case, and the other end of the fixing member is fastened to or separated from the protrusion by rotation about the hinge axis of the fixing member .

The heat sink may include a first plate disposed on one side of the light emitting unit, a second plate facing the first plate and having a curved surface and a flat surface, and a second plate disposed on the other side of the first plate, And the second plate may be provided with a flow hole for opening at least a part of the space.

The flat portion may be provided at a widthwise central portion of the second plate and extend along the longitudinal direction of the second plate, and the flow hole may extend along the longitudinal direction of the flat portion.

The curved surface portion of the second plate may include a first curved surface portion and a second curved surface portion that have different radii of curvature along the direction from the first plate toward the flow hole, The radius of curvature of the two curved portions may be smaller than the radius of curvature of the two curved portions.

The heat sink may be formed symmetrically with respect to the flow hole.

The heat sink further includes a plurality of radiating fins extending from the first plate toward the space portion in the height direction of the heat sink, wherein a height of the radiating fins is larger than a height of the first plate And at least one of the heat radiating fins may be formed with a fastening hole for coupling the heat sink to the first housing and the second housing.

In addition, the second plate may be formed in the form of a cover covering the widthwise side surface and the upper side of the heat sink.

Also, the heat sink and the second housing may be integrally formed, and the second housing may form an outer appearance of the front portion of the lighting apparatus.

The illumination device related to the present invention can realize light distribution optimized for various outdoor illumination environments.

Particularly, it is possible to implement individual light distribution by road or specific areas of the roadway in consideration of the specificity of road lighting.

In addition, various types of light distribution can be realized for each specific region through the combination of lenses having different light distribution curves.

In addition, it is possible to realize various additional types of light distribution in addition to the light distribution of each individual lens through the number of lenses having the individual light distribution, the order of arrangement, and rotation.

In addition, it is easy to assemble to adjust the light distribution characteristics, and the manufacturing cost can be reduced.

Further, by passing a plurality of curved portions having different radii of curvature in the process of passing the outside air through the heat sink, the flow rate of the outside air can be continuously changed.

Specifically, the convective heat exchange characteristics of the outside air can be continuously changed by increasing the flow velocity or decreasing the flow velocity in a specific section.

In addition, a secondary flow of the outside air of the heat sink can be generated through the primary flow generated inside the heat sink.

Also, the coanda effect can guide the flow of the outside air and improve the heat radiation characteristics of the heat sink.

Fig. 1 (a) is a front view of a lighting apparatus according to an embodiment of the present invention, and Fig. 1 (b) is a rear view of the lighting apparatus shown in Fig. 1 (a).
2 is a configuration diagram of a lighting apparatus according to an embodiment of the present invention.
3 is a partially exploded perspective view of the illumination device shown in Fig.
Fig. 4 is an exploded perspective view showing a coupling relation between the light emitting unit and the lens module. Fig.
5 (a) is a perspective view of a first lens constituting a lighting apparatus according to an embodiment of the present invention, and Fig. 5 (b) is a view showing a light distribution curve of the first lens shown in Fig. .
6 (a) is a perspective view of a second lens constituting a lighting apparatus according to an embodiment of the present invention, and Fig. 6 (b) is a perspective view showing a light distribution curve of the second lens shown in Fig. 6 .
Figures 7 (a) - (d) illustrate various embodiments relating to the placement of a lens module coupled to a substrate module.
8 is a perspective view of a heat sink constituting a lighting apparatus according to an embodiment of the present invention.
9 is a front view of the heat sink shown in Fig.
10 is a graph for explaining the relationship between the radius of curvature and the flow velocity of the outside air.
Fig. 11 (a) shows a state in which the first housing of the lighting apparatus shown in Fig. 1 is opened, and Fig. 11 (b) shows the structure of a fixing member provided in the first housing.

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 illumination device related to the present invention can be applied to both an outdoor illumination device such as a streetlight and an Indoor illumination device.

1 (a) and 1 (b) are a front view and a rear view of a lighting apparatus according to an embodiment of the present invention, and FIG. 2 is a schematic configuration diagram of a lighting apparatus according to an embodiment of the present invention.

1 (a) and 1 (b), a lighting apparatus 1 according to an embodiment of the present invention includes a light emitting unit 10, at least one lens module detachably mounted to the light emitting unit 10, A heat sink 30 in which the light emitting unit 10 is installed and a first housing 40 and a second housing 50 coupled to the heat sink 30.

The light emitting unit 10 may include a substrate 100. At this time, the substrate 100 may be formed of one or more substrate modules 110.

That is, the light emitting unit 10 may include at least one substrate module 110 and a plurality of LED arrays 120 (see FIG. 4) installed in the substrate module 110.

For example, the light emitting unit 10 may include a plurality of substrate modules 110, and each of the plurality of substrate modules 110 may include a plurality of LED arrays.

At this time, a plurality of lens modules 20 may be detachably mounted on the substrate module 110. Each of the plurality of lens modules 20 may be disposed to surround a corresponding one of the plurality of LED arrays installed in the substrate module 110.

As described above, since the substrate 100 is composed of the plurality of substrate modules 110, the maintenance of each substrate module 110 can be easily performed.

Also, since a plurality of lens modules 20 are detachably mounted on each of the plurality of substrate modules 110, the maintenance of each lens module 20 can be easily performed.

Each of the plurality of lens modules 20 may include a plurality of lenses 221. At this time, the plurality of lens modules 20 may each include a plurality of lenses 221 having different light distribution curves (i.e., light distribution characteristics).

For example, the plurality of lenses 221 provided in one lens module 20 may all be formed to have the same light distribution characteristics. At this time, the plurality of lenses 221 provided in the other lens module 20 may have the same light distribution characteristics and different light distribution characteristics from the one lens module 20.

Various types of light distribution can be realized by combining the lens modules 20 having different light distribution curves in the substrate module 110 as described above.

The first housing 40 may be provided at one end in the longitudinal direction of the heat sink 30. For example, the first housing 40 may be coupled to the heat sink 30 at a rear side in the longitudinal direction of the heat sink 30. [

In the first housing 40, one or more power modules 400 for supplying power to the light emitting unit 10 may be provided.

The power module 400 may be electrically connected to the light emitting unit 10. Accordingly, the power module 400 can supply power to the light emitting unit 10.

At this time, a plurality of power modules 400 may be provided in the first housing 40. The number of the power modules 400 may be determined according to at least one of the number of the substrate modules 110 and the number of the LED arrays 120.

Accordingly, when the number of the substrate modules 110 becomes equal to or greater than the predetermined number, or the load increases, or when the number of the LED arrays 120 becomes equal to or greater than the predetermined number, The number of modules 400 can also be increased.

Meanwhile, a plurality of connectors 131 for electrically connecting the substrate module 110 and the power module 400 may be provided on the side surfaces of the plurality of substrate modules 110, respectively.

Specifically, the illumination device 1 according to an embodiment of the present invention may further include a side substrate 130 disposed at one longitudinal end portion of the plurality of substrate modules 110.

The side substrate 130 and the plurality of substrate modules 110 may be mounted on the same surface of the heat sink 30. Specifically, the side substrate 130 and the plurality of substrate modules 110 may be mounted on the first plate 310 of the heat sink 30, respectively.

One end of each of the plurality of connectors 131 is fixed to the side board 130 connected to the power module 400 and the other end of each of the plurality of connectors 131 is connected to the plurality of board modules 110 To be detachably connected to one end portion in the longitudinal direction.

That is, the number of the connectors 131 may be the same as the number of the board modules 110.

Accordingly, when one of the plurality of board modules 110 has a problem related to the power supply, the corresponding connector 131 connected to one longitudinal end of each of the plurality of board modules 110 is connected and disconnected, The substrate module 110 having a problem can be easily determined.

Also, the second housing 50 may be provided at the other longitudinal end of the heat sink 30. For example, the second housing 50 may be coupled to the heat sink 30 at the front side in the longitudinal direction of the heat sink 30. [

At this time, the second housing 50 may form an outer appearance of the front portion of the lighting apparatus 1. [ Also, the second housing 50 may be integrally formed with the heat sink 30.

The heat sink 30, the first housing 40, and the second housing 50 may all be formed of the same material (for example, a metal material). However, it is preferable that the heat sink 30 is formed of a metallic material for heat dissipation, and that the first housing 40 and the second housing 50 are formed of resin to reduce the weight of the entire lighting apparatus 1.

On the other hand, when the illuminating device 1 is an outdoor illuminating device, the illuminating device 1 may further include a supporting member 60.

The support member 60 may be connected to the first housing 40. In one embodiment, the first housing 40 may be provided with an insertion hole 41. At this time, a part of the support member 60 may be positioned inside the first housing 40 through the insertion hole 41. [

In addition, the support member 60 may have an " a "shape or a" I "shape. In one embodiment, the support member 60 may include a pole portion fixed to a mounting surface such as a road or a guide, and an arm portion inserted into the first housing 40.

Hereinafter, with reference to Figs. 3 and 4, the light emitting unit provided in the lighting apparatus 1 will be described more specifically.

FIG. 3 is an exploded perspective view showing a coupling relationship between the light emitting unit and the heat sink shown in FIG. 1, and FIG. 4 is an exploded perspective view showing a coupling relationship between the light emitting unit and the lens module.

3, a lighting apparatus 1 according to an embodiment of the present invention may include a light transmitting member 70 surrounding the light emitting unit 10. [ The light transmitting member 70 may be formed of a glass.

A gasket 71 may be mounted on the periphery of the light transmitting member 70. The gasket 71 functions to improve watertightness and airtightness.

In addition, the illumination device 1 may include a front bracket 80 surrounding the periphery of the light transmission member 70. The front bracket 80 may be mounted to the heat sink 30. The front bracket 80 may be provided with an opening 81 for exposing the light transmitting member 70 to the outside.

In addition, the second housing 50 may be coupled to one side of the heat sink 30. The second housing 50 can be coupled to the heat sink 30 by one or more fastening members S. [ The heat sink 30 is formed with at least one coupling hole 331 to which the coupling member S is coupled. The coupling holes 231 will be described in detail with reference to FIGS. 8 and 9. FIG.

Referring to FIG. 4, the light emitting unit 10 includes a substrate module 110 and a plurality of LED arrays 120 mounted on the substrate module 110. The plurality of LED arrays 120 includes a first LED array 120-1, a second LED array 120-2, a third LED array 120-2, and a third LED array 120-3 arranged in sequence along the longitudinal direction L of the substrate module 110 -3) and a fourth LED array 120-4.

In addition, a plurality of lens modules 20 may be mounted on the substrate module 110 so as to surround each LED array 120. The plurality of lens modules 20 may be arranged along the longitudinal direction of the substrate module 110.

At this time, each of the plurality of LED arrays 120 includes a plurality of LEDs 121, and each of the plurality of lens modules 20 may include a plurality of lenses 221. For example, the number of the LEDs 121 included in one LED array 120 may be the same as the number of the lenses 221 provided in the lens module 20 corresponding to the LED array 120 have.

That is, the number of lenses 221 included in the specific lens module 20 may be determined to be equal to the number of the LEDs 121 included in the LED array 120 corresponding to the specific lens module 20.

A plurality of lens modules 20 are provided at the center of the lens module 20 with a first fastening hole 211 for mounting the lens module 20 to the substrate module 110, And a second fastening hole 111 may be formed at a position corresponding to the hole 211.

The plurality of lenses 221 of the lens module 20 are connected to the first and second fastening holes 211 and 211 so as to correspond to the positions of the plurality of LEDs 121 provided on the LED array 120. [ 111 along the circumferential direction.

That is, the plurality of lenses 221 provided in the lens module 20 may be provided along the circumferential direction of the lens module 20 around the first fastening hole 211, The plurality of LEDs 121 may be provided at positions corresponding to the plurality of lenses 221 with the second fastening hole 111 as a center.

The first plate 310 of the heat sink 30 may have a third fastening hole 311 formed at a position corresponding to the first fastening hole 211 and the second fastening hole 111.

Accordingly, one coupling member (not shown) passes through the first coupling hole 211, the second coupling hole 111, and the third coupling hole 311, and the lens module 20 and the substrate module 110 And may be mounted on the heat sink (i.e., the first plate of the heat sink).

The distance between the plurality of LEDs 121 of the LED array 120 may be the same along the longitudinal direction L and the width direction W of the substrate module 110. Further, the plurality of LEDs 121 may be arranged in N rows and N columns (N > 1), respectively.

At this time, each of the LED arrays 120-1 to 120-4 can take on the light distribution in different areas of the illumination space. For example, each of the LED arrays 120-1 to 120-4 may individually take on the light distribution of the divided illumination space.

In addition, a lens module 20 composed of lenses 221 having different light distribution characteristics may be mounted on each of the LED arrays 120-1 to 120-4.

Hereinafter, the arrangement of lenses having different light distribution characteristics will be described in detail with reference to Figs. 5 to 7. Fig.

5 (a) is a perspective view of a first lens constituting a lighting apparatus according to an embodiment of the present invention, and Fig. 5 (b) is a view showing a light distribution curve of the first lens shown in Fig. .

6 (a) is a perspective view of a second lens constituting a lighting apparatus according to an embodiment of the present invention, and Fig. 6 (b) is a sectional view of a second lens of the second lens shown in Fig. 6 Curve.

That is, the lens module 20 according to an embodiment of the present invention may include a plurality of lenses 221, and the plurality of lenses 221 may include a first lens 221-1, And a second lens 221-2 having a light distribution characteristic different from that of the first lens 221-1.

More specifically, FIG. 5A shows the first lens 221-1, and FIG. 6A shows the second lens 221-2. 5B shows another light distribution curve (i.e., a light distribution characteristic) for the first lens 221-1 and FIG. 6B shows a light distribution curve (light distribution characteristic) corresponding to the second lens 221-2 That is, a light distribution characteristic).

On the basis of the state shown in FIG. 5A, the first lens 221-1 may have a left / right symmetrical shape. Further, the first lens 221-1 may have an up / down symmetrical shape. At this time, the left / right direction of the first lens 221-1 can be used in coincidence with the traveling direction of the vehicle.

On the basis of the state shown in FIG. 6 (a), the second lens 221-2 may have a left / right symmetrical shape. Further, the second lens 221-2 may have an asymmetric shape in an up / down direction. At this time, the left / right direction of the second lens 221-2 can be used in coincidence with the traveling direction of the vehicle. Further, the second lens 221-2 can be used in a state in which the upper side thereof is directed to the side (opposite direction of the vehicle).

5 (b) and 6 (b), the first lens 221-1 and the second lens 221-2 have different shapes and light distribution curves (i.e., light distribution characteristics) .

7, a plurality of lens modules 20 mounted on the light emitting unit 10 is provided with a plurality of first lenses 221-1 having a first light distribution curve (i.e., a first light distribution characteristic) At least one second lens module (21) and at least one second lens module (21-2) provided with a plurality of second lenses (221-2) having a second light distribution curve (i.e., a second light distribution characteristic) different from the first light distribution curve 22).

That is, the plurality of lens modules 20 mounted on the light emitting unit 10 include at least one first lens module 21 having a first light distribution characteristic and at least one second lens module 22 having a second light distribution characteristic .

4 and 7, the first lens module 21 is mounted on the substrate module 110 so as to surround the first LED array 120-1, and the second lens module 22 May be mounted on the substrate module 110 to surround the second LED array 120-2. Specifically, the first lens module 21 and the second lens module 22 may be mounted on the substrate module 110 so as to surround different LED arrays, respectively.

In this case, the light distribution curve (or the light distribution characteristic) of the light emitted from the first LED array 120-1 is different from the light distribution curve of the light emitted from the second LED array 120-2. That is, when a plurality of lens modules 21 and 22 having different light distribution characteristics are mounted on the substrate module 110, the light distribution characteristics of the divided illumination spaces can be individually varied.

The light distribution characteristic of the lens module 20 is determined by the number of the first and second lens modules 21 and 22 and the arrangement order of the first and second lens modules 21 and 22, (21, 21) may be varied based on at least one of the angles rotated about the center of the LED array (120).

At this time, the order of arrangement of the first and second lens modules 21 and 22 may be determined along the longitudinal direction L of the substrate module 110.

In order to adjust the number of the first and second lens modules 21 and 22 and the arrangement order of the first and second lens modules 21 and 22, the first lens module 21 and the second lens module 22 are preferably formed to have the same size (e.g., size or specification).

In addition, the first lens module 21 or the second lens module 22 can be selectively mounted on the same LED array 120. [ Specifically, the first lens module 21 and the second lens module 22 may be formed so as to be compatible (or replaceable) with respect to the single LED array 120.

As described above, each of the LED arrays 120-1 to 120-4 may include a plurality of LEDs 121 arranged along the circumferential direction of each of the LED arrays 120-1 to 120-4.

The plurality of first lenses 221-1 of the first lens module 21 are disposed along the circumferential direction of the first lens module 21 so as to correspond to the positions of the LEDs 121 of the LED array 120 . Likewise, the plurality of second lenses 221-2 of the second lens module 22 are arranged along the circumferential direction of the second lens module 22 so as to correspond to the positions of the LEDs 121 of the LED array 120 .

The number of the first lenses 221-1 of the first lens module 21 and the number of the second lenses 221-2 of the second lens module 22 are set to be the same as the number of the LEDs 121 of the LED array 120 ). ≪ / RTI >

For example, when four LEDs 121 are arranged in two rows and two columns in one LED array 120, the first lenses 221-1 of the first lens module 21 are provided in four , And two rows and two columns corresponding to the four LEDs 121. Likewise, the four second lenses 221-2 of the second lens module 22 may also be arranged in two rows and two columns, corresponding to the four LEDs 121. [

The first lens module 21 and the second lens module 22 may be provided with first fastening holes 211 at the center thereof. At this time, the plurality of first lenses 221-1 may be provided along the circumferential direction of the first lens module 21 with the first fastening hole 211 as a center. Similarly, the plurality of second lenses 221-2 may be provided along the circumferential direction of the second lens module 22 with the first fastening hole 211 as a center.

The distance between the first fastening hole 142 and the first lens 221-1 and the distance between the second fastening hole 111 and the second lens 221-2 may be the same. In addition, the angular distance of two adjacent first lenses 221-1 and the distance of two adjacent second lenses 221-2 may be the same.

Through the above structure, the first lens module 21 and the second lens module 22 can be compatible (or replaceable) with respect to the single LED array 120.

The substrate module 110 may be provided with a plurality of second fastening holes 111 for mounting the first lens module 21 or the second lens module 22. [ The plurality of second fastening holes 111 may be provided along the longitudinal direction L of the substrate module 110.

The illumination device 1 may further include a plurality of coupling members for mounting the first lens module 21 to the substrate module 110 or mounting the second lens module 22 to the substrate module 110, (E. G., A screw).

The coupling member passes through the first coupling hole 211 of the first lens module 21 and the second coupling hole 111 of the substrate module 110 and is inserted into the second coupling hole 111 of the substrate module 110, Respectively. Alternatively, the coupling member may pass through the first fastening hole 211 of the first lens module 21 and the second fastening hole 111 of the substrate module 110 in order to form the heat sink 30 And may be fastened to the third fastening hole 311 (see FIG. 3).

The coupling member may pass through the first coupling hole 211 of the second lens module 22 and may be coupled to the second coupling hole 111 of the substrate module 110. The second fastening member passes through the first fastening hole 211 of the second lens module 22 and the second fastening hole 111 of the substrate module 110 in order to form the heat sink 30, And may be fastened to the third fastening hole 311 formed in the first fastening hole 311.

Meanwhile, the second fastening hole 111 may be located at the center of the LED array 120. That is, a plurality of LEDs 121 constituting the LED array 120 may be arranged along the circumferential direction of the ED array 120 with the second fastening hole 111 as a center.

As described above, the light distribution characteristics (or the light distribution curves) of the plurality of lens modules 20 are determined by the angle at which the first or second lens modules 21 and 22 are rotated with respect to the center of the LED array 120 .

The first lens module 21 may be mounted on the substrate module 110 while being rotated around the first fastening hole 211 by a predetermined angle. For example, when the first lens module 21 includes four first lenses 221-1 arranged in two rows and two columns, four light distribution characteristics (Light distribution curve).

Specifically, as the first lens module 21 is rotated a predetermined angle (for example, 90 degrees) around the first fastening hole 211 from a predetermined initial position, the first lens module 21 is rotated, A plurality of first lenses 221-1 of the LED array 120 may be rotated to a position different from the initial position surrounding the LEDs 121 of the LED array 120, respectively.

Similarly, as the second lens module 22 is rotated from the predetermined initial position by a predetermined angle around the second fastening hole 111, the plurality of second lenses 221- 2 may be rotated to a different position from the initial position that surrounds each LED 121 of the LED array 120, respectively.

That is, the first lens module 21 or the second lens module 22 may be selectively replaceable or compatible with respect to the single LED array 120. The plurality of first lens modules 21 that are each rotated at different angles with respect to the center of the LED array 120 and can be disposed on the substrate module 110 may be selectively positioned relative to the single LED array 120 May be in a replacement or compatible state. Similarly, a plurality of second lens modules 22, each of which can be rotated at different angles relative to the center of the LED array 120 and disposed on the substrate module 110, May be in a replacement or compatible state.

Referring to FIG. 7A, a plurality of lens modules 20 having a specific light distribution curve (that is, a light distribution characteristic) may be mounted on one substrate module 110. For example, a plurality of second lens modules 22 having a second light distribution characteristic may be disposed along the length direction of one substrate module 110. [

At this time, each of the second lens modules 22 may be disposed on the substrate module 110 in the same direction. That is, each of the second lens modules 22 may be disposed on the substrate module 110 while being rotated at the same rotation angle.

Referring to FIG. 7B, a plurality of first lens modules 21 and a plurality of second lens modules 22 are aligned in a longitudinal direction of the substrate module 110 on one substrate module 110 So that they can be arranged alternately.

At this time, the plurality of first lens modules 21 may be disposed on the substrate module 110 in the same direction. That is, each of the first lens modules 21 can be disposed on the substrate module 110 while being rotated at the same rotation angle. Similarly, the plurality of second lens modules 22 may be disposed on the substrate module 110 in the same direction. That is, each of the second lens modules 22 may be disposed on the substrate module 110 while being rotated at the same rotation angle.

As described above, by separately mounting the first and second lens modules 21 and 22 having different light distribution characteristics on one substrate module 110, different light distribution characteristics can be realized in the divided illumination regions.

7C, a plurality of first lens modules 21 having a first light distribution characteristic may be disposed along a longitudinal direction of the substrate module 110 in one substrate module 110 .

At this time, at least one first lens module 21 'of the plurality of first lens modules 21 may be disposed on the substrate module 110 in a state rotated in a direction different from that of the remaining first lens module 21 have. For example, only one of the first lens modules 21 'of the plurality of first lens modules 21 disposed on the substrate module 110 is directed in a direction different from the other first lens modules 21, And can be arranged in an angularly rotated state.

Referring to FIG. 7 (d), a plurality of second lens modules 22 having a second light distribution characteristic may be disposed along the length direction of one substrate module 110.

At this time, the plurality of second lens modules 22 may be disposed so as to be oriented in a direction different from that of the adjacent second lens module 22. That is, in the illustrated embodiment, each of the four second lens modules 22 is arranged on the substrate module 110 while being rotated at a predetermined angle (for example, 90 degrees or 180 degrees) . For example, each of the plurality of second lens modules 22 may be rotated on the substrate module 110 in a clockwise (CW) 90 degree or 180 degree angle with respect to the adjacent second lens module 22 .

In this way, even when a plurality of first lens modules 21 are mounted on the substrate module 110 or only a plurality of second lens modules 22 are mounted on the substrate module 110, Different light distribution characteristics can be realized in the divided illumination region by changing the rotated angle of the module 21 or the second lens module 22. [

Hereinafter, the heat sink 30 according to the embodiment of the present invention will be described in detail with reference to FIG.

8 is a perspective view of a heat sink constituting a lighting apparatus according to an embodiment of the present invention. 9 is a front view of the heat sink shown in Fig.

Referring to Figs. 8 and 9, the lighting apparatus 1 according to the embodiment of the present invention includes a heat sink 30. Fig. Further, the light emitting unit 10 described above is disposed in the heat sink 30.

Such a heat sink 30 may have a shape extending in the width direction W and the longitudinal direction L. [

Specifically, the heat sink 30 includes a first plate 310 on which the light emitting unit 10 is disposed, a second plate 320 facing the first plate 310, And a space 350 formed between the first and second plates 320 and 320.

For example, the light emitting unit 10 may be disposed on one side of the first plate 310, and the space 350 may be formed on the other side of the first plate 310 (i.e., And the second plate 320, as shown in FIG. At this time, the first plate 310 and the second plate 320 may be integrally formed.

The second plate 320 may include curved portions 321 and 322 and a flat portion 323. The second plate 320 may be provided with a flow hole 340 for opening at least a part of the space 350.

Accordingly, the fluid (i.e., air) inside and outside the space portion 340 can flow through the space portion 350.

The planar portion 323 of the second plate 320 is provided at the center of the width direction of the second plate 320 (i.e., the width direction W of the heat sink 30) (That is, the longitudinal direction L of the heat sink 30).

The flow holes 340 may be formed to extend along the longitudinal direction of the planar portion 323 (i.e., the longitudinal direction L of the heat sink 30).

At this time, the flow hole 340 may be formed to have a longer length extending along the longitudinal direction of the planar portion 323 than a length extending along the width direction of the planar portion 323. Here, the flow hole 340 may be referred to as a slit.

The heatsink 30 may have a shape symmetrical in the width direction with respect to the flow hole 340. Accordingly, the second plate 320 may also have a shape symmetrical in the width direction with respect to the flow hole 340.

For example, the heat sink 30 may have a shape that is symmetrical with respect to the center axis H of the heat sink 30. 9, the x-axis represents the width direction W of the heat sink 30, and the y-axis represents the height direction of the heat sink 30. As shown in Fig.

The central axis H is substantially parallel to the y-axis. Therefore, the heat sink 30 may have a symmetrical shape with respect to the height direction along the central axis H of the heat sink 30. [

At this time, the widthwise center of the flow hole 340 and the center axis H may be positioned coaxially. In other words, the heat sink 30 may have a symmetrical shape with respect to the flow hole 340.

Meanwhile, the flow hole 340 may be formed to extend over the entire length of the planar portion 323 (see FIG. 8). That is, both end portions of the planar portion 323 in the longitudinal direction may be formed to be opened by the flow holes 340. Specifically, the planar portion 323 may be separated by the flow holes 340, and may be provided with two planar portions 323 on one side and the other side in the width direction. For example, the length of the planar portion 323 may be the same as the length of the flow hole 340.

The shape of this flow hole 340 facilitates the flow of fluid (i.e., air) in and out of the space 340 through the space 350.

On the contrary, the flow hole 340 may be formed to extend over a part of the length of the planar portion 323 (see FIG. 3). That is, since the flow holes 340 do not extend to both ends in the longitudinal direction of the flat portion 323, both longitudinal ends of the flat portion 323 can be formed not to be opened by the flow holes 340 . Specifically, the length of the flat portion 323 may be longer than the length of the flow hole 340.

The shape of this flow hole 340 improves the rigidity of the heat sink 30 (i.e., the rigidity of the second plate 320).

The second plate 320 may be provided with a plurality of curved portions 321 and 322 having curved radii r1 and r2 along the height direction of the heat sink 30. [

When the plurality of curved portions 321 and 322 have different radii of curvature r1 and r2, the flow rate of the external air flowing along the second plate 320 may vary. As a result, the convective heat exchange characteristics of the outside air flowing along the second plate 320 can be changed.

The curved portions 321 and 322 of the second plate 320 may have a first curved portion 321 having different curvature radii along the direction from the second plate 310 toward the flow hole 340 And a second curved surface portion 322 in this order.

The curvature radius r1 of the first curved surface portion 321 may be smaller than the curvature radius r2 of the second curved surface portion 322. [

The curvature center C1 of the first curved surface portion 321 and the curvature center C2 of the second curved surface portion 322 are located in different regions defined by the second plate 320, . According to one embodiment, the first curved surface portion 321 may have a convex shape upward along the y-axis direction. In addition, the second curved surface portion 322 may have a concave shape downward along the y-axis direction.

The arc length l1 of the first curved surface portion 321 may be shorter than the arc length l2 of the second curved surface portion 322. [

The inflection point P provided at the boundary between the first curved surface portion 321 and the second curved surface portion 322 is positioned so as not to overlap with the light emitting unit 110 along the height direction of the heat sink 30 .

Specifically, the inflection points P may be biased toward the both ends of the heat sink 30 in the width direction W. [ The first curved surface portion 321 may be positioned so as not to overlap with the light emitting unit 10 along the height direction of the heat sink 30.

A planar portion 340 (also referred to as a first planar portion) may be provided between the second curved portion 322 and the flow hole 230. At this time, the plane portion 340 may be formed parallel to the first plate 310.

A vertical portion 325 (also referred to as a first vertical portion) orthogonal to the first plate 310 may be provided between the first plate 310 and the first curved portion 321. A connection part may be provided between the vertical part 325 and the first plate 310.

Here, the connection portion may include a vertical portion 326 (also referred to as a second vertical portion) and a planar portion 327 (also referred to as a second planar portion). The connection part may be provided with a floating slit communicating with the space 340.

The boundary between the second vertical portion 326 and the first plate 310 may be a curved surface portion. Similarly, the boundary between the second vertical portion 326 and the second flat surface portion 327 may be formed as a curved surface portion. The boundary between the second planar portion 327 and the first vertical portion 325 may be a curved surface.

Meanwhile, the space 340 may be provided with a plurality of radiating fins 330 having a predetermined height.

The heat sink 30 may include a plurality of heat radiating fins 330 extending from the first plate 310 toward the space 340 in the height direction of the heat sink 30.

For example, the plurality of radiating fins 330 may be disposed on a side of the first plate 310 opposite the side where the light emitting unit 10 is disposed.

Here, the heat dissipation fin 330 may be positioned to overlap the light emitting unit 10 along the height direction of the heat sink 30.

The second plate 320 may be formed in the form of a cover covering the widthwise side surface and the upper side of the heat sink 30. In other words, the second plate 320 may be formed so as to open both ends in the longitudinal direction of the heat sink 30 and cover only both sides and the upper side in the width direction. Of course, at least a part of the upper side of the heat sink 30 is opened by the flow hole 340 described above.

At this time, the plurality of radiating fins 330 may be spaced apart at predetermined intervals along the width direction of the first plate 310.

The height of the plurality of radiating fins 330 may be gradually decreased from the widthwise center of the first plate 310 to both widthwise sides of the first plate 310. That is, the height of the plurality of radiating fins 330 may be reduced toward both sides in the width direction of the heat sink 30 with respect to the flow holes 340.

Accordingly, the shape of the second plate 320 may also be formed such that the height of the second plate 320 decreases from the central portion in the width direction of the second plate 320 toward both side portions in the width direction.

At least one of the plurality of radiating fins 330 may be formed with a fourth fastening hole 331 for coupling the heat sink 30 with the first housing 40 and the second housing 50 have.

For example, the fourth fastening hole 331 may include two heat dissipating fins 330 provided at a center portion in the width direction of the heat sink 30 and two heat dissipating fins 330 provided at both sides of the heat sink 30 in the width direction Respectively.

The heat sink 30 is connected to the front housing (i.e., the second housing 50) disposed in front of the heat sink 30 and the rear housing (i.e., the first housing 40), the fourth fastening holes 331 may be provided at both ends of the heat radiating fins 330 in the longitudinal direction, respectively.

Hereinafter, with reference to Fig. 10, the heat radiation effect generated by the above-described heat sink 30 will be described.

10 is a graph for explaining the relationship between the radius of curvature and the flow velocity of the outside air.

Referring to FIGS. 8 to 10, when the light emitting unit 10 is operated, air in the space 350 can flow out through the flow holes 340. At this time, the outflow of the air in the space 350 through the flow hole 340 can be referred to as a primary flow (upward flow).

On the other hand, the outside air can be continuously introduced into the space 350 through both open ends of the heat sink 30 in the longitudinal direction.

In addition, external air may flow toward the flow hole 340 along the outer surface of the second plate 320. At this time, the external air flowing along the outer surface of the second plate 320 can be referred to as a secondary flow. Further, the secondary flow can be generated or accelerated by the primary flow.

In addition, the flow rate of the outside air may increase during the passage through the first curved portion 321, and the flow velocity may decrease during the passage through the second curved portion 322. Particularly, a coanda effect appears in the process of the outside air passing through the first curved portion 321. [

Coanda effect refers to the shape of a flowing fluid flowing along the surface of an object. In addition, the Coanda effect shows a phenomenon in which a material bent in a flowing fluid is flowed while bending along the fluid.

That is, when the light emitting unit 10 operates, the temperatures of the first plate 310 and the space 350 are increased. At this time, the primary flow is caused by the temperature difference between the high temperature part and the low temperature part. Also, the secondary flow described above can be generated or accelerated by the primary flow.

Also, the primary flow may perform the same function as the driving source of the secondary flow. Thus, the heat generated in the light emitting unit 110 can be easily diverted to the outside by the primary flow and the secondary flow.

10 is a graph for explaining the relationship between the radius of curvature r and the flow velocity V of the outside air. As described above, the flow rate of the external air flowing along the outer surface of the second plate 320 of the heat sink 30 is increased and decreased by the curved surfaces 321 and 322 provided on the second plate 320, Is related to the radius of curvature.

In the above equations (1) and (2), P represents the pressure, r represents the radius of curvature, and V represents the flow velocity.

The Coanda effect can be confirmed from the Euler equation of Equation (1). From the fact that the motion of the fluid is influenced by the geometric element, it is possible to integrate with respect to r, so that equation (2) can be derived.

At this time, the relational expression shown in Fig. 10 can be obtained on the assumption that P and p are constant.

Referring to FIG. 10, the change of the flow velocity passing through the curved portion according to the increase of the radius of curvature r is as follows. That is, as the radius of curvature r increases, the flow velocity V decreases and as the radius of curvature r decreases, the flow velocity V increases.

Also, as the flow velocity V increases, the convection heat exchange coefficient h increases.

Therefore, the lighting apparatus 1 according to the embodiment of the present invention can improve the heat radiation performance through the coanda effect by the curved surfaces 321 and 322 of the heat sink 30. [

Particularly, the flow velocity of the fluid (outside air) is increased at the first curved surface portion 321 having a relatively small radius of curvature, so that the temperature of both side portions in the width direction of the heat sink 30 provided with the first curved surface portion 321 Can be remarkably reduced.

Hereinafter, with reference to FIG. 11, the structure of the fixing member provided in the first housing 40 of the lighting apparatus according to the embodiment of the present invention will be described.

11 (a) schematically shows the first housing 40 of the lighting apparatus 1 shown in Fig. 1 in an opened state, and Fig. 11 (b) Fig.

11, the first housing 40 of the lighting apparatus 1 according to an embodiment of the present invention includes an upper case 410 and a lower case 420 coupled to the upper case 410 .

In the first housing 40, one or more power modules 400 may be installed.

At this time, the first housing 40 needs to be formed in an easy-to-open structure in order to perform maintenance of the power module 400 and maintenance of the components related to the power module 400.

The first housing 40 according to the embodiment may have one end in the longitudinal direction of the upper case 410 so that the upper case 410 can be opened from the lower case 420, (Not shown).

One end portion of the upper case 410 and the lower case 420 in the longitudinal direction is connected to the upper case 410 and the upper case 410 farther from the heat sink 30 in a state where the upper case 410 and the lower case 420 are coupled to each other. (Hereinafter also referred to as "distal end") of the lower case 420. Fig.

Specifically, hinge portions 411 and 421 may be provided at one longitudinal end portion of the upper case 410 and the lower case 420.

For example, the hinge portions 411 and 421 may include a shaft support member 411 provided at one longitudinal end portion of one of the upper case 410 and the lower case 420, And a shaft member 421 provided at one longitudinal end of the other of the lower case 420 and disposed to be rotatable through the shaft supporting member 411. [

In the illustrated embodiment, the shaft member 421 is provided at one longitudinal end of the lower case 420, and the shaft supporting member 411 is provided at one longitudinal end of the upper case 410, (Not shown).

The shaft member 421 may be integrally formed with the lower case 420 and the shaft support member 411 may be integrally formed with the upper case 410.

The upper case 410 may be rotated with respect to the hinge portions 411 and 421 and opened from the lower case 420 when maintenance or the like of the power module 400 is required.

At this time, since the lower case 420 is coupled through the third fastening hole 311 of the heat sink 30 (for example, because it is bolted), the upper case 410 is connected to the hinge The lower case 420 may be fixed to the heat sink 30 even if the lower case 420 is rotated from the lower case 420 to the lower case 420 by being rotated.

Specifically, when the longitudinal direction ends of the upper case 410 and the lower case 420 near the heat sink 30 are referred to as "proximal ends" in a state where the upper case 410 and the lower case 420 are coupled to each other The upper case 410 is rotated with respect to the hinge portions 411 and 421 disposed at the distal end of the upper case 410 to be guided by the lower case 410 420).

Meanwhile, one of the upper case 410 and the lower case 420 may be provided with a fixing member 425 on both sides in the width direction.

The other one of the upper case 410 and the lower case 420 may be provided with protrusions 415 at both sides in the width direction at positions corresponding to the fixing member 425 to be fastened to the fixing member 425 have.

For example, the lower case 420 is provided with recesses 419 on both sides in the width direction, and the recess 419 is formed with the protrusion 415 protruding outward in the width direction of the lower case 420 . At this time, the protrusion 415 provided in the recess 419 may be formed integrally with the lower case 420.

At this time, the width of the protrusion 415 may be the same as the width of the recess 419, and the height of the protrusion 415 is preferably lower than the height of the recess 419.

The fixing member 425 is provided on both widthwise sides of the other longitudinal end of the lower case 420 (i.e., the proximal end of the lower case), and the protrusion 415 is provided on the upper case 410 (That is, the proximal end portion of the upper case) in the width direction.

Therefore, after the upper case 410 is closed to the lower case 420, the fixing member 425 is fastened to the protrusion 415 so that the upper case 410 and the lower case 420 can be locked with each other. That is, the upper case 410 is closed to the lower case 420 by fastening the fixing member 425 and the protrusion 415 in a state where the upper case 410 is closed to the lower case 420 .

Therefore, when the upper case 410 is to be opened from the lower case 420, the user lifts the proximal end of the upper case 410 after releasing the fixing member 425 from the protrusion 415 something to do.

According to an embodiment of the present invention, one end of the fixing member 425 may be hinged to one of the upper case 410 and the lower case 420. At this time, the other end of the fixing member 425 can be fastened to or separated from the protrusion 415 by rotation about the first hinge axis 426 of the fixing member 425.

For example, in the illustrated embodiment, one end of the fastening member 425 is hinged to the lower case 420 by a first hinge axis 426. At this time, the cross section of the fixing member 425 may have a " C "or" U "

Specifically, the first hinge shaft 426 may be provided on a lower surface of both side portions in the width direction of the lower case 420. The other end of the fixing member 425 may be rotated up and down with respect to the first hinge shaft 426.

A protrusion 415 may be formed at a position corresponding to the fixing member 425 on both sides in the width direction of the upper case 410 and a protrusion 415 may be formed on the protrusion 415 with reference to a second hinge axis 416 A clip member 417 formed to be rotatable may be provided.

For example, the clip member 417 may be rotatably mounted on the upper surface of the protrusion 415 with reference to the second hinge shaft 416.

The clip member 417 may be provided on the inner side in the width direction of the first housing 40 than the fixing member 425. That is, in a state where the upper case 410 is locked to the lower case 420, the fixing member 425 may be provided to cover the clip member 417 in the width direction.

In the width direction side portions of the upper case 410, protruding pieces 418 are provided on the upper portions of the protruding portions 415. At least a part of the clip member 417 can be fastened to or separated from the protruding piece 418 by the rotation of the fixing member 425.

At this time, the clip member 417 may be formed in a rectangular shape, and the second hinge shaft 416 may be provided on one side of the rectangular clip member 417, And can be fastened to or separated from the protruding piece 418 by the rotation of the clip member 417 with respect to the second hinge axis 416.

The clip member 417 is sandwiched between the other end of the fixing member 425 and the projecting piece 418 while the upper case 410 is locked to the lower case 420. [

Hereinafter, the operation of the fixing member 415 and the clip member 417 will be described in more detail.

When the user tries to open the upper case 410 from the lower case 420, the user can push the other end of the fixing member 425 outward in the width direction of the first housing 40.

That is, when the user tries to open the upper case 410 from the lower case 420, the user can press the opposite end of the end of the fixing member 425, which is provided with the first hinge axis 426, (Not shown).

The other end of the fixing member 425 is rotated about the first hinge shaft 426 provided at one end of the fixing member 425 and the other end of the fixing member 425 and the protrusion 418 The clip member 417 is released. That is, the clip member 417 rotates with respect to the second hinge shaft 416, and a side of the clip member 417 facing the side provided with the second hinge shaft 416 is separated from the protrusion piece 418 Is released.

The user can lift the proximal end portion of the upper case 410 to open the upper case 410 from the lower case 420.

Conversely, if the user wishes to lock the upper case 410 and the lower case 420 after closing the upper case 410 to the lower case 420, the user performs the opposite process to that described above Can be performed.

The user can pull the other end of the fixing member 425 inward in the width direction of the first housing 40 while the upper case 410 is closed to the lower case 420. [

The other end of the fixing member 425 is rotated about the first hinge shaft 426 provided at one end of the fixing member 425 and the other end of the fixing member 425 and the protrusion 418 One side of the clip member 417 is sandwiched.

For example, the clip member 417 may have a rectangular shape, and the second hinge axis 416 may be provided on one side of the clip member 417 having a rectangular shape. The side opposite to the side provided with the second hinge shaft 416 can be sandwiched between the other end of the fixing member 425 and the protruding piece 418.

The clip member 417 rotates about the second hinge axis 416 with the rotation of the other end of the fixing member 425 toward the inside in the width direction of the lower case 40, The side opposite to the side where the hinge shaft 416 is provided may be fixed between the protruding piece 418 and the other end of the fixing member 425.

The side of the clip member 417 on which the hinge shaft 416 of the clip member 417 is provided is moved in the direction opposite to the above operation, that is, in accordance with the rotation of the other end of the fixing member 425 toward the outside in the width direction of the lower case 40 May be separated from between the protruding piece 418 and the other end of the fixing member 425.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, The present invention may be modified in various ways. Therefore, modifications of the embodiments of the present invention will not depart from the scope of the present invention.

1: Lighting device 10: Light emitting unit
20: Lens module 30: Heatsink
40: first housing (rear housing) 50: second housing (front housing)
110: substrate module 120: LED array
130: side substrate 310: first plate
320: second plate 321: first curved portion
322: second curved surface portion 323: flat surface portion
330: radiating fin 340: flowing hole
350:

Claims (19)

A light emitting unit including a plurality of substrate modules, and a plurality of LED arrays mounted on the substrate module;
At least one lens module detachably mounted to the light emitting unit;
A heat sink provided with the light emitting unit;
A first housing provided at one longitudinal end of the heat sink;
A second housing provided at the other longitudinal end of the heat sink; And
And at least one power module provided in the first housing for supplying power to the light emitting unit,
Wherein each of the plurality of substrate modules is detachably mounted with a corresponding lens module, each lens module is arranged to surround a plurality of LED arrays installed in a corresponding substrate module,
Wherein the lens module includes at least one first lens module having a first light distribution characteristic and at least one second lens module having a second light distribution characteristic different from the first light distribution characteristic,
The light distribution characteristic of the illumination space is changed based on at least one of the number of the first and second lens modules and the arrangement order of the first and second lens modules,
The heat sink includes a first plate on one side of the light emitting unit, a second plate facing the first plate and having a curved surface and a flat surface, and a second plate on the other side of the first plate and the second plate And a space formed thereon,
And the second plate is provided with a flow hole for opening at least a part of the space portion. The method according to claim 1,
Wherein the light emitting unit includes a plurality of substrate modules,
Wherein a plurality of LED arrays are respectively installed in each of the plurality of substrate modules. delete The method according to claim 1,
Wherein the lens module is provided at its center with a fastening hole for fastening the lens module to the substrate module,
Wherein the lens module is disposed along the longitudinal direction of the substrate module. 5. The method of claim 4,
Wherein the LED array includes a plurality of LEDs, the lens module includes a plurality of lenses,
Wherein a plurality of lenses of the lens module are provided along a circumferential direction around the fastening hole so as to correspond to positions of a plurality of LEDs provided in the LED array. delete 3. The method of claim 2,
And a plurality of connectors for electrically connecting the substrate module and the power module to each other are provided on a side surface of each of the plurality of substrate modules. 8. The method of claim 7,
Further comprising a side substrate disposed at one longitudinal end of the plurality of substrate modules,
Wherein one end of the plurality of connectors is fixed to the side substrate connected to the power module,
And the other end of the plurality of connectors is detachably connected to one longitudinal end portion of the plurality of substrate modules. The method according to claim 1,
Wherein the number of the power supply modules is determined according to at least one of the number of the substrate modules and the number of the LED arrays. The method according to claim 1,
The first housing includes an upper case and a lower case coupled to the upper case,
Wherein one end in the longitudinal direction of the upper case is hinged to one end in the longitudinal direction of the lower case. 11. The method of claim 10,
A fixing member is provided on both sides in the width direction of the other longitudinal direction end of one of the upper case and the lower case,
And protrusions to be fastened to the fixing member at positions corresponding to the fixing member are provided on both widthwise sides of the other longitudinal direction end of the other of the upper case and the lower case. 12. The method of claim 11,
Wherein one end of the fixing member is hinged to one of the upper case and the lower case,
And the other end of the fixing member is fastened or separated to the projection by rotation about the hinge axis of the fixing member. delete The method according to claim 1,
Wherein the flat portion is provided at a widthwise central portion of the second plate and extends along the longitudinal direction of the second plate,
And the flow hole extends along the longitudinal direction of the flat portion. The method according to claim 1,
Wherein the curved surface portion of the second plate sequentially includes a first curved portion and a second curved portion having different radii of curvature along the direction from the first plate toward the flow hole,
Wherein the curvature radius of the first curved portion is smaller than the curvature radius of the second curved portion. The method according to claim 1,
Wherein the heat sink is formed symmetrically with respect to the flow hole. The method according to claim 1,
Wherein the heat sink further comprises a plurality of radiating fins extending from the first plate toward the space portion in a height direction of the heat sink,
The height of the radiating fins is gradually decreased from the widthwise center of the first plate to both widthwise sides of the first plate,
Wherein at least one of the heat radiating fins has a fastening hole for coupling the heat sink to the first housing and the second housing. 18. The method of claim 17,
Wherein the second plate is formed in the form of a cover that covers the lateral side portion and the upper side of the heat sink in the width direction. The method according to claim 1,
Wherein the heat sink and the second housing are integrally formed, and the second housing forms an outer appearance of the front portion of the lighting apparatus.

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