KR20160049369A - Lighting device - Google Patents

Abstract

A lighting device according to an embodiment of the present invention comprises: a housing including a power connection hole; at least one light source module disposed on a lower surface of the housing; a power source unit spaced from an upper part of the housing and supplying power to the light source module; and a connection unit which connects the housing and the power source unit, and includes a cable hole through which a cable passes and a connection body surrounding the cable hole, wherein a part of the connection body is inserted into the power connection hole. The housing includes: a base plate defining a space in which the light source module is located; and a heat dissipation part which is disposed to surround the rim of the base plate, and includes a plurality of first heat radiation fins provided in a circumferential direction and a plurality of second heat radiation fins respectively provided between two adjacent first heat radiation fins. External air flows through a space between two adjacent first heat radiation fins, a space between the first heat radiation fin and the second heat radiation fin, and a space between two adjacent second heat radiation fins.

Description

LIGHTING DEVICE

An embodiment relates to a lighting device.

Generally, indoor or outdoor lighting is used as a lamp or a fluorescent lamp. In the case of such a bulb or fluorescent lamp, there is a problem that its lifetime is short and it is frequently exchanged. In addition, a conventional fluorescent lamp may deteriorate over time, and the illuminance may gradually decrease.

In order to solve such a problem, a light emitting diode (LED) capable of realizing excellent controllability, fast response speed, high electric light conversion efficiency, long life, low power consumption, Various types of lighting modules are being developed.

Light emitting diodes (LEDs) are a type of semiconductor devices that convert electrical energy into light. The light emitting diode has advantages of low power consumption, semi-permanent lifetime, fast response speed, safety, and environmental friendliness compared with conventional light sources such as fluorescent lamps and incandescent lamps. Accordingly, much research has been carried out to replace an existing light source with a light emitting diode, and a light emitting diode has been increasingly used as a light source for lighting devices such as various liquid crystal displays, electric sign boards, and street lamps used outside the room.

However, the lighting apparatus using the light emitting element has a problem that the power supply unit is located on the top of the housing or the side surface of the lighting apparatus, so that the wiring is complicated and exposed to the outside, resulting in difficulty in work or exposure to electrical hazards.

Further, when a plurality of light source modules are used, there is a problem that wiring work of a plurality of light source modules is not easy.

In addition, there is a problem of how to solve the waterproofing problem together with wiring when connecting a plurality of such light source modules.

And, when the power source unit is separated from the housing, there is a problem of these connection, electrical wiring and waterproofing.

Further, in a lighting apparatus in which a light emitting element is used, since the light emitting element is easily damaged by heat, research is underway to effectively discharge the heat generated in the light emitting element.

It is an object of the present invention to provide an illuminating device which facilitates electrical connection between a power source unit and a light source module which are separated from a housing, and which is easy to be sealed.

It is another object of the present invention to provide a housing having excellent heat radiation performance.

An illumination apparatus according to an embodiment of the present invention includes a housing including a power connection hole, at least one light source module disposed on a lower surface of the housing, a power source unit spaced apart from the upper portion of the housing to supply power to the light source module, And a connection body for connecting the power supply unit and a cable through which the cable passes, and a connection body surrounding the cable hole, wherein a part of the connection body includes a connection unit inserted into the power connection hole, A plurality of first radiating fins provided between the first radiating fins disposed adjacent to the circumference of the base plate and the first radiating fins adjacent to the base plate defining the space in which the light source module is positioned; And a space between the adjacent two first radiating fins and a space between the adjacent two first radiating fins, Through a second space between the two second radiating fins adjacent to the space and between the first heat radiation fin and the second heat radiation fin characterized by comprising a flow of outside air.

According to the embodiment of the present invention, there is an advantage that the lighting can be easily implemented with a desired power consumption by changing the number of the light source modules coupled to the housing.

In addition, in the embodiment, since the housing in which the light source module is located and the power source unit are connected to each other by using the connection unit, there is an advantage that the heat generated in the power source unit is limited from being transmitted to the light source module.

Also, in the embodiment, since the power source unit is connected to the light source module through the cable hole of the connection unit and the connector coupling unit of the light source module is disposed adjacent to the power source connection hole, Lt; / RTI >

In addition, even though a plurality of light source modules are coupled, the embodiment has a structure in which the light source modules are coupled to the light source fixing grooves formed in the inner surface of the power connection hole, thereby easily connecting a plurality of light source modules and easily forming a sealing structure .

In addition, the embodiment has an advantage of preventing the occurrence of water leakage because the space where the power source unit and the light source module are coupled is arranged around the power connection hole to seal the small area.

In addition, the embodiment has a structure in which the front cover presses the support protrusions protruding from the support substrate, so that there is an advantage that a separate fastening member is not required when the light source module is coupled to the housing, .

Further, the embodiment has a structure of a heat dissipating portion that improves the contact time of air to the housing, and there is an advantage of effectively discharging the heat transferred to the housing.

In addition, the embodiment has the advantage that, by using the fastening guide, the insertion of the connecting unit is prevented from flowing when fastened to the power connecting groove.

1 is a perspective view of a lighting apparatus according to an embodiment of the present invention,
2 is a top plan view of a lighting device according to an embodiment of the present invention,
Fig. 3 is an exploded perspective view of the illumination device of Fig. 1,
4 is a perspective view of a power unit and a connection unit according to an embodiment of the present invention,
FIG. 5A is an enlarged perspective view of a connection unit according to an embodiment of the present invention, FIG.
FIG. 5B is a sectional view of a lower casing and a connecting unit according to an embodiment of the present invention, FIG.
6 is a plan view of a housing according to an embodiment of the present invention,
7A is a perspective view showing a heat dissipation portion of the housing,
FIG. 7B is a cross-sectional view of the heat dissipating unit of one embodiment,
8A is a plan view of a power connection hole formed in a housing according to an embodiment of the present invention,
FIG. 8B is a plan view showing a state where an insertion portion of a connection unit is inserted into a power connection hole according to an embodiment,
8C is a cross-sectional view illustrating a state where an insertion portion of a connection unit is inserted into a power connection hole according to an embodiment,
9 is a plan view showing a state where a light source module is coupled to a housing according to an embodiment of the present invention,
FIGS. 10A and 10B are perspective views of a light source module according to an embodiment of the present invention,
FIG. 11 is a reference view illustrating a coupling of a light source module to a housing according to an embodiment of the present invention;
FIG. 12 is a sectional view for explaining the engagement of the front cover according to an embodiment of the present invention, FIG.
13 is an exploded perspective view of a front cover according to an embodiment of the present invention,
14A is a cross-sectional view of another connecting unit according to another embodiment of the present invention, Fig.
FIG. 14B illustrates an inner surface of a power connection hole according to another embodiment of the present invention; FIG.
15 is a plan view of a lighting apparatus according to still another embodiment of the present invention.

Hereinafter, embodiments will be described in detail with reference to the drawings.

FIG. 1 is a perspective view of a lighting apparatus according to an embodiment of the present invention, FIG. 2 is a top plan view of the lighting apparatus according to an embodiment of the present invention, and FIG. 3 is an exploded perspective view of the lighting apparatus of FIG.

1 to 3, the lighting apparatus 10 of the embodiment includes a housing 200 including a power connection hole 211, at least one light source module 600 disposed on the bottom surface of the housing 200, A connection unit 400 and a connection unit 400 for connecting the housing 200 and the power supply unit 100. The power supply unit 100 includes a power supply unit 100 which is positioned above the power supply unit 200 and supplies power to the light source module 600, And a light source fixing unit 450 (635) for fixing the light source module 600 to the light source module 600.

The illumination device 10 of another embodiment includes a housing 200 including a power connection hole 211, at least one light source module 600 disposed at a front surface of the housing 200, And a front cover 500 defining a space in which the light source module 600 is positioned and transmitting light generated in the light source module 600.

The power supply unit 100 supplies power to the light source module 600.

Specifically, the power supply unit 100 controls the overall operation of the lighting apparatus and supplies driving power.

For example, the power supply unit 100 may include a power supply unit 113 that generates driving power and generates and outputs a control signal, and a casing 110 that receives the power supply unit 113.

The power supply unit 113 generates driving power and a control signal to be supplied to the light source module 600. The power supply unit 113 may include a main board and a plurality of components. The main board may be a printed circuit board. The components are mounted on the main board and electrically connected to the main board.

Also, the power supply unit 113 may be a power supply unit (PSU). At this time, the power supply unit 113 can control the light source module 600 according to a wireless control signal received from the communication module.

The casing 110 accommodates the power supply unit 113. Specifically, the casing 110 defines a space in which the lower casing 111 and the upper casing 112 are coupled to receive the power supply unit 113.

Particularly, a sealing member (not shown) is placed on the rim of the lower casing 111 and the upper casing 112 to be waterproof.

On the outer surface of the casing 110, a support member 120 for fixing the casing 110 to the outer space is provided.

Specifically, the support member 120 is formed in a rectangular plate shape having a predetermined thickness and a transverse direction, and both ends of the support member 120 are rotatably fixed to the outer surface of the casing 110.

The power unit 100 is spaced apart from the housing 200. This is to prevent the heat generated in the power unit 100 from being transmitted to the light source module 600 to prevent the light source module 600 from being overheated.

Specifically, the power source unit 100 is disposed above the housing 200 and spaced apart from the housing 200.

Here, the upper direction means the Z axis direction, and the lower direction means the direction opposite to the Z axis. Here, the lateral direction means the X-axis or the Y-axis direction and the vertical direction to the Z-axis.

At this time, the housing 200 and the power source unit 100 are separated by the connection unit 400. The connection unit 400 fixes the power source unit 100 and the housing 200 and separates them from each other, thereby suppressing heat transfer.

In particular, the connection unit 400 may have a smaller size than the casing 200 of the housing 200 and the casing 110 of the power unit 100.

Hereinafter, the connecting unit will be described in detail with reference to the drawings.

5a is an enlarged perspective view of a connecting unit according to an embodiment of the present invention, FIG. 5b is a perspective view of a lower casing according to an embodiment of the present invention, FIG. Sectional view of the connecting unit.

  4 and 5, the connection unit 400 transfers the power of the power source unit 100 to the light source module 600, so that the power source unit 100 is separated from the housing 200.

For example, the connection unit 400 has a cylindrical shape with a cable hole 430 through which a cable (not shown) passes.

Specifically, the connection unit 400 includes a cable hole 430 through which a cable (not shown) passes, and a connection body 410 that surrounds the cable hole 430.

The connecting body 410 receives the cable in the inner cable hole 430.

The connection unit 400 may be formed integrally with the casing 110. Specifically, the cable hole 430 of the connection body 410 of the connection unit 400 communicates with the interior of the casing 110. That is, the opening of the lower casing 111 communicates with the cable hole 430.

The connection unit 400 and the casing 110 are integrally formed and coupled to the upper portion of the housing 200 to facilitate replacement and repair in the event of a failure.

The cable connected to the power source unit 113 located inside the casing 110 is extended to the cable hole 430 through the opening of the lower casing 111.

The connection body 410 connects the housing 200 and the power unit 100. A part of the connection body 410 is inserted into the power connection hole 211.

A reinforcing rib 411 may be formed on the outer surface of the connection body 410 along the longitudinal direction of the connection body 410. The reinforcing ribs 411 improve the strength and elastic restoring force of the connecting body 410.

Specifically, the connection body 410 includes an insertion portion 440 inserted into the power connection hole 211 and a coupling portion 420 coupled with the periphery of the power connection hole 211.

The insertion portion 440 is defined as a region adjacent to the cable hole 430 in the connection body 410 forming the rim of the cable hole 430 and the connection portion 420 defines the rim of the cable hole 430 Is defined as an area adjacent to the outer surface of the connecting body 410, which is made of a metal.

In particular, referring to FIG. 5, the insertion portion 440 is formed to surround the cable hole 430.

The insertion portion 440 is inserted into the power connection hole 211 and exposed to the power connection hole 211.

The insertion portion 440 is formed to correspond to the shape of the power connection hole 211. For example, the power connection hole 211 may be formed in a circular shape (in the X-Y axis plane), and the insertion portion 440 may also be formed in a circular shape.

The insertion portion 440 is formed so as to protrude from the coupling portion 420, thereby effectively preventing moisture from flowing from the outside.

Preferably, the insertion portion 440 is formed so as to protrude below the lower surface of the coupling portion 420, and the step corresponds to the thickness of the housing 200.

The insertion portion 440 is formed with an alignment protrusion 442 formed in the alignment groove 212 formed in the power connection hole 211.

The alignment protrusion 442 determines the positions of the insertion portion 440 and the power connection hole 211 at the time of coalescence.

Specifically, the alignment protrusions 442 are formed protruding from the outer surface of the insertion portion 440.

A light source fixing groove 450 of the light source fixing units 450 and 635 is formed on the inner surface of the insertion portion 440.

That is, the light source fixing units 450 and 635 fix the light source module 600 to the connection unit 400. The light source fixing units 450 and 635 include a light source fixing groove 450 and a light source fixing protrusion 635 that is formed in the light source fixing groove 450.

Here, the light source fixing groove 450 is recessed outward on the inner surface of the connection body 410, which forms the cable hole 430.

That is, the light source fixing groove 450 is recessed outward on the inner surface of the insertion portion 440 in the X-Y axis plane.

It is preferable that the light source fixing groove 450 is constrained to the light source fixing protrusion 635 described later.

The light source fixing groove 450 fixes the light source module 600 and determines the position of the light source module 600.

The light source fixing groove 450 is formed by recessing the inner surface of the insertion portion 440 so that the light source module 600 is easily fixed to the insertion portion 440 and the moisture introduced from the outside is inserted into the coupling portion 420 Lt; / RTI >

That is, when the protrusions or holes are formed in the housing 200 formed of a plate material, leakage is generated through them, so that the cable holes 430 of the connection unit 400, which are coupled to the power connection holes 211 already formed, Thereby improving the waterproof performance and increasing the space efficiency.

The light source fixing grooves 450 may be disposed on the inner surface of the cable hole 430 in the circumferential direction.

The plurality of light source fixing grooves 450 provide space for coupling the plurality of light source modules 600.

Since one light source fixing protrusion 635 is formed in one light source module 600, one light source module 600 is coupled to one light source fixing groove 450.

Thus, the power consumption of the lighting apparatus 10 can be determined according to the number of the light source modules 600 of a single standard.

For example, when one of the light source modules 600 has a power consumption of 30 W, and when three of them are combined, the power consumption of the lighting apparatus 10 is 90 W and the power consumption of the lighting apparatus 10 is 120 W do.

Accordingly, various power consumption can be easily assembled by one light source module 600 and a lighting device.

More specifically, the light source fixing grooves 450 form a group of two to four, and a plurality of such groups may be symmetrically positioned about the cable holes 430 in the circumferential direction of the cable holes 430 have.

Accordingly, the power consumption of the lighting apparatus 10 can be adjusted according to the number of the light source modules 600 coupled thereto. In addition, since the light source module 600 is disposed symmetrically with respect to the cable hole 430 in the light source fixing groove 450 formed of a group, the light source module 600 can irradiate uniform light irrespective of the number .

The coupling portion 420 surrounds the power connection hole 211 and is coupled to the housing 200.

For example, the engaging portion 420 is in contact with the upper surface of the housing 200 while being overlapped with the periphery of the power connection hole 211.

The engaging portion 420 defines a space through which the housing fastening member 810 is coupled and a space where the sealing member is located.

Accordingly, the coupling portion 420 is coupled to the housing 200 to prevent water from penetrating into the power connection hole 211 formed in the housing 200.

Particularly, since the engaging portion 420 has a stepped portion with respect to the inserting portion 440, the penetration of water into the power connecting hole 211 is more effectively prevented.

The engaging portion 420 is formed to surround the insertion portion 440.

An external sealing groove 421 and a body coupling groove 427 are formed in the coupling part 420 of the connection body 410.

The body engaging groove 427 provides a place where the housing fastening member 810 such as a bolt engages.

The body coupling groove 427 is formed in the coupling portion 420, and the housing coupling member 810 penetrating the housing 200 is inserted and coupled.

Specifically, the body coupling groove 427 is positioned corresponding to the housing coupling hole 213 (FIG. 8) formed in the housing 200.

A plurality of body engaging grooves 427 are formed along the circumferential direction of the engaging portion 420 so as to surround the inserting portion 440.

The body engaging groove 427 is recessed upward from the bottom surface of the engaging portion 420.

Since the housing fastening member 810 passing through the housing fastening hole 213 is fastened to the body fastening groove 427, the external water can be introduced through the housing fastening hole 213 and / or the body fastening groove 427 have.

Therefore, at least the outer sealing member 471 (see FIG. 8) surrounding the body coupling groove 427 is disposed in the coupling portion 420.

Specifically, the external sealing member 471 is disposed so as to surround the power coupling hole 211, the insertion portion 440, and the body coupling groove 427 of the coupling portion 420.

More specifically, the outer sealing member 471 forms a closed space (in plan view) inside and is disposed along the circumferential direction of the engaging portion 420. [ That is, the outer sealing member 471 has a ring shape.

That is, the outer sealing member 471 is brought into contact with the engaging portion 420 and one surface (more specifically, the upper surface) of the housing 200.

The outer sealing member 471 may be a rubber material having elasticity.

For example, the outer sealing member 471 is accommodated in the outer sealing groove 421.

Specifically, the external sealing groove 421 is disposed in the coupling portion 420 to surround the insertion portion 440 and the body coupling groove 427. That is, the external sealing groove 421 forms a closed space (in a plane) along the circumferential direction of the engaging portion 420.

More specifically, the external sealing groove 421 is formed by recessing a portion of the engaging portion 420.

It is preferable that the size (height) of the outer sealing groove 421 is smaller than the size of the outer sealing member 471 so that the outer sealing member 471 can be sufficiently pressed.

That is, the external sealing groove 421 is formed in a ring shape to enclose the body coupling groove 427.

Further, in order to improve the waterproof performance, the embodiment may further include the inner sealing member 473 (see Fig. 8).

The inner sealing member 473 contacts one surface of the coupling part 420 and the housing 200 to seal the area where the body coupling groove 427 is formed in the power connection hole 211 and the coupling part 420.

Specifically, the inner sealing member 473 is disposed so as to be wrapped by the body coupling groove 427. [

More specifically, the inner sealing member 473 is disposed in the engaging portion 420 in a ring shape surrounding the inserting portion 440, and the body engaging groove 427 extends from the engaging portion 420 to the inner sealing member 473 And an outer sealing member 471 is disposed so as to surround the body coupling groove 427.

The inner sealing member 473 prevents moisture introduced through the body coupling groove 427 and the housing coupling hole 213 from flowing into the cable hole 430.

For example, the inner sealing member 473 may be received in the inner sealing groove 425.

Specifically, the inner sealing groove 425 is formed corresponding to the inner sealing member 473.

That is, the inner sealing groove 425 is disposed so as to surround the insertion portion 440, and is surrounded by the body coupling groove 427. That is, the inner sealing groove 425 forms a closed space (in a plane) along the circumferential direction of the engaging portion 420.

More specifically, the inner sealing groove 425 is formed by recessing a portion of the engaging portion 420.

The height (height) of the inner sealing groove 425 is preferably smaller than the size (height) of the inner sealing member 473 so that the inner sealing member 473 can be sufficiently pressed.

The housing 200 has a power connection hole 211 formed therein and defines a space through which a cable for electrically connecting the power source unit 100 and the light source module 600 is inserted and in which the light source module 600 is located.

In addition, the housing 200 serves to discharge heat.

Hereinafter, the housing 200 will be described in detail with reference to the drawings.

FIG. 6 is a plan view of a housing according to an embodiment of the present invention, FIG. 7A is a perspective view illustrating a heat dissipating unit of the housing, and FIG. 7B is a sectional view of a heat dissipating unit of an embodiment.

6 and 7, the housing 200 includes a power connection hole 211 at the center thereof, and provides a space around the power connection hole 211 to which the light source module 600 is coupled.

For example, the housing 200 includes a base plate 210 and a heat radiating portion 220.

The base plate 210 and the heat dissipating unit 220 are integrally formed, and a metal material such as aluminum, which is excellent in thermal conductivity, is used.

In particular, the housing 200 may be formed of a plate material to maximize thermal conductivity.

The base plate 210 is formed with a power connection hole 211 at a center and a space where the light source module 600 is positioned around the power connection hole 211 is defined.

Specifically, the base plate 210 may have a circular shape on a plane (X-Y axis plane).

A plurality of hook holes 217 are formed along the circumferential direction on the rim of the base plate 210.

The hook 520 of the front cover 500 penetrates through the hook hole 217 and is fastened.

In particular, the hook hole 217 is disposed on the outside of the light source module 600 on a plane.

In addition, a plurality of bolt holes 219 may be formed along the circumferential direction on the rim of the base plate 210. A bolt passing through the front cover 500 is coupled to the bolt hole 219.

Of course, it is preferable that the hook hole 217 and the bolt hole 219 are located outside the region where the light source module 600 is located in the base plate 210 for waterproofing.

A hook ring 217 and a sealing ring 560 are disposed inside the bolt hole 219 to enclose the light source module 600.

The hook hole 217 and the bolt hole 219 are located outside the sealing ring 560 to prevent moisture from entering the light source module 600 from the outside.

Referring to FIG. 7, the heat dissipating unit 220 dissipates the heat transferred from the base plate 210.

The first heat radiation fins 221 and the second heat radiation fins 222 are arranged along the circumferential direction of the housing 200. The first heat radiation fins 221 and the second heat radiation fins 222 are disposed around the periphery of the base plate 210. [

A plurality of first radiating fins 221 are positioned along the circumferential direction. The second radiating fins 222 are positioned between the adjacent two first radiating fins 221.

Here, when natural convection occurs, the space 231 between the adjacent two first radiating fins 221, the space S between the first radiating fins 221 and the second radiating fins 222, Outer air flows through the space 232 between the first and second heat-dissipating fins 222.

The structure of the heat dissipating unit 220 as described above is to increase the residence time of the outside air and the flow path A and the convective heat exchange area.

Specifically, a first heat dissipating hole 231 is provided between two adjacent first heat dissipating fins 221, and a second heat dissipating hole 232 is provided between adjacent two second heat dissipating fins 222 .

That is, the first radiating fins 221 are spaced apart from each other along the circumferential direction of the housing 200, and the second radiating fins 222 are spaced apart from each other along the circumferential direction of the housing 200 Respectively.

It is preferable that the first heat dissipating hole 231 is positioned to face the second heat dissipating fin 222 and the second heat dissipating hole 232 is positioned to face the first heat dissipating fin 221.

The outer air flowing into the first heat dissipating hole 231 collides with the second heat dissipating fin 222 so that the flow path A can be bent once and the outer air can flow through the first heat dissipating fin 221 and the second heat dissipating fin 222 and then discharged to the outside through the second heat dissipating hole 232. [

On the other hand, the outside air may be branched to both sides in the space S between the first radiating fins 221 and the second radiating fins 222.

Therefore, the flow path A of the outside air can be changed in the process of passing through the heat discharging part 220, and in particular, the flow path A of the outside air flows at least twice By forming the flow path A in a complicated manner, the residence time of the outside air passing through the heat discharging unit 220 and the heat exchange area for convection can be increased.

The first radiating fins 221 and the second radiating fins 222 may extend from the base plate 210, respectively.

The first radiating fins 221 and the second radiating fins 222 may extend from the base plate 210 so as to have a predetermined radius of curvature and the first radiating fins 221 and the second radiating fins 222 may have a radius of curvature Can be extended from the base plate 210, respectively.

In addition, the first radiating fin 221 and the second radiating fin 222 may have a radius of curvature protruding in different directions. That is, the second radiating fins 222 may protrude from the first radiating fins 221 toward the power source unit 100.

The first radiating fins 221 and the second radiating fins 222 are mounted on the rim of the housing 200 formed of a plate material with a first radiating fin 221 and a second radiating fin 222 at predetermined pitches along the circumferential direction of the housing 200 And the first radiating fins 221 and the second radiating fins 222 may be formed protruding in opposite directions to each other.

The heat dissipating unit 220 is provided with a first radiating fin 221 extending from the base plate 210 and a rim 229 connected to the second radiating fins 222 extending from the base plate 210.

Specifically, the rim portion 229 forms the outer rim of the heat dissipating unit 220 and is connected to the outer ends of the first radiating fins 221 and the second radiating fins 222.

The rim portion 229 maintains the shape of the first radiating fin 221 and the second radiating fin 222 to reinforce the rigidity of the housing 200. [

Further, the rim portion 229 can be bent in one direction to improve rigidity. Specifically, the rim portion 229 is bent in the direction of the power unit 100.

The first radiating fin 221 may extend from the base plate 210 and include a curved surface portion 221a having a predetermined radius of curvature and a flat surface portion 221b bent from the curved surface portion 221a.

That is, as the curved surface portion 221a and the flat surface portion 221b are bent, the first radiating fins 221 may have a structure protruding in a direction opposite to the power source unit 100. [

The flat portion 221b may be provided on the same plane as the rim portion 229 of the housing 200.

The first radiating fins 221 and the second radiating fins 222 may be formed of a metal material or a resin material having excellent thermal conductivity.

For example, the first radiating fins 221 and the second radiating fins 222 may be formed by punching and bending one region of the housing 200 formed of an aluminum plate.

The first radiating fins 221 and the second radiating fins 222 may have a shape that widens as the distance from the base plate 210 increases.

At this time, the first radiating fins 221 and the second radiating fins 222 may have the same width.

Also, a heat sink 300 for releasing the heat transferred from the housing 200 may be coupled to the housing 200.

For example, the heat sink 300 may have various shapes such that the contact area with the outside air is increased.

Specifically, the heat sink 300 is coupled to the upper surface of the base plate 210.

More specifically, the heat sink 300 has an opening 330 corresponding to the power connection hole 211 at the center, and has a smaller width than the base plate 210.

The heat sink 300 includes a main plate 310 formed of an aluminum plate having excellent thermal conductivity and a heat protrusion 320 protruding from the main plate 310.

Particularly, the heat sink 300 is formed with a coupling region 313 through which the coupling member penetrates, and the coupling region 313 is located outside the region enclosed by the sealing ring 560, which will be described later.

The power supply connection hole 211 provides a place through which a cable for electrically connecting the power supply unit 100 and the light source module 600 is passed.

That is, the power connection hole 211 is located in the center of the housing 200, and a part of the connection unit 400 is inserted and coupled, and the cable passing through the connection unit 400 is a space through which the cable passes.

In addition, a periphery of the power connection hole 211 provides a place where the light source module 600 and the connection unit 400 are coupled.

Therefore, the embodiment seals the power connection hole 211 and the periphery thereof, thereby preventing leakage of the cable.

In addition, the power supply unit 100 and the light source module 600 are disposed around the power connection hole 211 to seal a small area, thereby easily preventing leakage.

FIG. 8A is a plan view of a power connection hole formed in a housing according to an embodiment of the present invention, FIG. 8B is a plan view showing a state where an insertion portion of a connection unit is inserted into a power connection hole according to an embodiment, In which the inserting portion of the connecting unit is inserted.

Referring to FIG. 8, the power connection hole 211 is located at the center of the housing 200 as viewed from above.

Specifically, the power connection hole 211 is disposed at the center of the base plate 210 with a shape corresponding to the base plate 210. The power connection hole 211 preferably has a circular shape.

In consideration of heat transfer and waterproof performance between the power source unit 100 and the light source module 600, the width of the power source unit 100 and the housing 200 ) ≪ / RTI >

When the size of the power connection hole 211 is smaller than that of the power source unit 100 and the light source module 600, the heat of the power source unit 100 is prevented from being transferred to the light source module 600, The power connection hole 211 can be sealed.

Meanwhile, the light source module 600 and the connection unit 400 are provided in the vicinity of the power connection hole 211. That is, the periphery of the power connection hole 211 is one area of the base plate 210 forming the rim of the power connection hole 211.

An alignment groove 212 may be formed in the periphery of the power connection hole 211 in which the alignment protrusion 442 formed in the insertion portion 440 is formed.

The alignment groove 212 is formed with the alignment protrusion 442 to determine the positions of the insertion portion 440 and the power connection hole 211 at the time of tacking.

Specifically, the alignment groove 212 is formed by extending a portion of the power connection hole 211 outward.

In addition, the embodiment further includes a positioning unit that determines the position of the housing 200 and the light source module 600.

Here, the positioning unit includes positioning holes 215 and 633 formed to correspond to the housing 200 and the light source module 600, respectively. The positioning holes 215 and 633 include a housing positioning hole 215 formed in the housing 200 and a light source positioning hole 633 formed in the light source module 600.

The light source positioning hole 633 is formed in the light source module 600 so as to correspond to the housing positioning hole 215. This will be described later.

The housing positioning hole 215 may be coupled to the light source coupling member 820 through a connector 699 described later.

For example, the housing positioning hole 215 is disposed around the power connection hole 211 so as to surround the power connection hole 211.

Particularly, for waterproofing, the positioning holes 215 and 633 are positioned so as to overlap with the inner sealing groove 425 formed in the engaging portion 420, and the inner sealing member 473 is positioned between the positioning holes 215 and 633 ).

Alternatively, the positioning unit may include a positioning hole formed in any one of the housing 200 and the light source module 600, and a positioning hole formed in the other of the housing 200 and the light source module 600, (Not shown).

A housing coupling hole 213 is formed in the base plate 210 to correspond to the body coupling groove 427.

The housing coupling member 810 is passed through the housing coupling hole 213.

Specifically, a plurality of housing coupling holes 213 are formed along the circumferential direction of the power connection hole 211 so as to surround the power connection hole 211.

More specifically, as shown in FIG. 8C, the housing coupling hole 213 may be formed so as to be surrounded by the outer sealing member 471 to prevent moisture from entering from the outside.

That is, the housing coupling hole 213 is disposed in the periphery of the power connection hole 211, the external sealing member 471 is positioned so as to surround the housing coupling hole 213, and the power connection hole 211 and the housing An inner sealing member 473 is positioned between the engaging holes 213.

FIG. 9 is a plan view showing a state where a light source module is coupled to a housing according to an embodiment of the present invention. FIGS. 10A and 10B are a perspective view of the light source module viewed from different directions, 11 is a reference diagram illustrating the coupling of a light source module to a housing according to an embodiment of the present invention.

9-11, the light source module 600 may include any means for generating light.

For example, the light source module 600 may include a plurality of light emitting devices 610 and a support substrate 630 that supplies power to the light emitting devices 610 and supports the light emitting devices 610. However, the present invention is not limited thereto, and the light emitting device 610 may be formed as a package type including the light emitting device 610.

The light emitting device 610 may be, for example, a light emitting diode. The light emitting diode may be, for example, a colored light emitting diode that emits light such as red, green, blue, or white, or a UV (Ultra Violet) light emitting diode that emits ultraviolet light.

In addition, the light source module 600 may generate a single color, and the light generated from the plurality of light emitting devices 610 may be mixed to emit white light.

A plurality of light emitting devices 610 may be covered by a lens 620 corresponding to each of the light emitting devices 610.

The lens 620 changes the optical properties of the light generated in the light emitting element 610. Specifically, the lens 620 may be formed in a hemispherical shape to extend the directivity angle of the light generated by the light emitting element 610.

The supporting substrate 630 supplies power to the light emitting element 610 and provides a space in which the light emitting element 610 is located.

For example, the supporting substrate 630 includes a printed circuit board.

Since the shape of the supporting substrate 630 is not limited as long as the width of the supporting substrate 630 increases as one direction extends from the other end to the other end, . ≪ / RTI >

The light source module 600 includes a support projection 650, a connector coupling portion 640, and a connector seating groove 631.

The support protrusions 650 are pressed by the front cover 500 to fix the light source module 600 in a space formed by the housing 200 and the front cover 500.

The support protrusion 650 is supported on the front cover 500 and presses the support protrusion 650 when the front cover 500 is coupled to the housing 200.

Accordingly, the use of the support protrusion 650 advantageously eliminates the need for a separate fastening member when the light source module 600 is coupled to the housing 200, and has the advantage of preventing water inflow due to engagement of the fastening members exist.

For example, the support protrusion 650 protrudes from the support substrate 630.

Specifically, the support protrusions 650 protrude from the support substrate 630 higher than the light emitting element 610 (and the lens 620). This is to prevent the light emitting element 610 from being pressed when the front cover 500 presses the support protrusion 650.

More specifically, the support protrusion 650 can be pressed by the optical plate 550. This will be described later.

The support protrusion 650 can be elastically deformed. The support protrusion 650 may include an elastic member 651 that is connected to the support member 653 protruding from the support substrate 630 and the support member 653 and is made of an elastic material more than the support member 653. [ .

The connector coupling portion 640 is coupled to a connector 699 to which a cable is connected.

The connector coupling portion 640 is located at one end of the supporting substrate 630. Here, one end of the supporting substrate 630 is disposed adjacent to the power connection hole 211 with a narrow width.

The supporting board 630 also includes a connector seating groove 631 on which the connector 699 is seated. At this time, the connector seating groove 631 is formed to correspond to the position of the connector 699, and the supporting board 630 can be formed by being recessed.

The light source positioning hole 633 may be formed in the connector seating groove 631. The light source positioning member 633 penetrates through the light source coupling member 820 penetrating the connector 699.

Further, the light source module 600 further includes a light source fixing protrusion 635 formed in the light source fixing groove 450.

The light source fixing protrusion 635 is formed in the light source fixing groove 450 to fix the light source module 600.

The light source fixing protrusion 635 is protruded from the supporting substrate 630.

Specifically, the light source fixing protrusion 635 protrudes from a surface of the supporting substrate 630 facing the surface on which the light emitting device 610 is located.

Further, the light source fixing protrusion 635 is located at one end of the supporting substrate 630. [ One end of the supporting substrate 630 is disposed adjacent to the power supply connection hole 211 and is a region having a smaller width than the other end of the supporting substrate 630.

One end of the light source module 600 is overlapped with the power connection hole 211 and the light source fixing protrusion 635 is located in a region overlapping the power connection hole 211 in the light source module 600.

There is no limitation on the shape of the light source fixing protrusion 635, but it is preferable that the light source fixing groove 635 has a shape that does not flow in the light source fixing groove 450 when the light source fixing groove 450 is fitted.

The light source module 600 is disposed on the bottom surface of the housing 200.

Specifically, the light source module 600 is disposed on the bottom surface of the base plate 210.

At this time, the width of the light source module 600 is expanded as the distance from the power connection hole 211 increases. That is, the width of the light source module 600 is increased as the light source module 600 moves from one end (in detail, one end of the support substrate 630) toward the other end of the light source module 600. One end of the light source module 600 is disposed adjacent to the power connection hole 211.

Accordingly, the required number of the light source modules 600 can be coupled by surrounding the power connection hole 211 according to the shape of the light source module 600.

As shown in FIG. 9, the light source module 600 is radially disposed around the power connection hole 211 as a whole.

A plurality of light source modules 600 can be connected to the power source connection hole 211 so that the light source module 600 can be connected to the power source connection hole 211 only in the vicinity of the power source connection hole 211, Thus, there is an advantage of easily forming a waterproof structure.

One end of the power supply connection hole 211 and one end of the light source module 600 are covered by a cap 800.

The cap 800 is inserted and coupled to the power connection hole 211.

FIG. 12 is a cross-sectional view illustrating a front cover according to an embodiment of the present invention, and FIG. 13 is an exploded perspective view of a front cover according to an embodiment of the present invention.

Referring to FIGS. 12 and 13, the front cover 500 is coupled to the housing 200 to define a space in which the light source module 600 is positioned, and transmits light generated in the light source module 600.

When the front cover 500 is coupled to the housing 200, the support protrusion 650 of the light source module 600 is pressed to fix the light source module 600 without the fastening member.

For example, when the front cover 500 is integrally formed with the housing 200, the front cover 500 may have a structure that seals the area where the light source module 600 is located and the outside.

As another example, the front cover 500 may be composed of a plurality of components.

Specifically, the front cover 500 covers the base plate 210 and the lower portion of the light source module 600.

The front cover 500 includes a cover body 510, a front cover coupling member, and an optical plate 550.

The cover body 510 is formed to surround the light source module 600 and the power connection hole 211.

Specifically, the cover body 510 surrounds the power supply connection hole 211 and defines a space in which the light source module 600 is located between the power supply connection hole 211 and the cover body 510.

More specifically, the cover body 510 is formed in a ring shape. In addition, a lower portion of the cover body 510 is formed with an extension portion 440 extending outward.

The extension unit 440 guides light generated in the light source module 600.

The front cover 500 further includes a sealing ring seating portion 530 on which a sealing ring 560 (or an optical plate 550) described later is seated.

The sealing ring seating portion 530 seats the sealing ring 560.

Specifically, the seal ring seating portion 530 is formed to extend inward from the cover body 510. [ That is, the sealing ring seating portion 530 has a ring shape extending inward from the cover body 510.

In addition, the end of the sealing ring seat 530 is bent upward to prevent the seated ring 460 from being released.

The front cover engaging member engages the cover body 510 and the housing 200.

For example, the front cover engaging member includes a hook 520 that is coupled through a hook hole 217 formed in the housing 200. A plurality of hooks 520 may be disposed along the periphery of the cover body 510.

Specifically, the hook 520 is formed so as to protrude upward from the cover body 510.

Alternatively, the front cover coupling member may be a bolt (not shown) which is inserted through the housing 200 and the cover body 510 and is fastened.

The optical plate 550 covers the lower side of the light source module 600 and converts the optical properties of the light source module 600.

In addition, the optical plate 550 covers the lower part of the light source module 600 to protect the light source module 600 from the outside.

For example, the optical plate 550 can diffuse the light incident from the light source module 600 into surface light.

Scattering particles scattering light incident from the light source module 600 may be included in the optical plate 550 so that the light emitted from the light source module 600 can be converted into light.

According to the embodiment, the optical plate 550 can be made of PMMA (polymethylmethacrylate) or transparent acrylic resin in a flat type or a wedge type, and can be formed of a glass material And plastic materials, but is not limited thereto.

Specifically, the optical plate 550 may have a plate or film form.

Preferably, the optical plate 550 may include a synthetic resin material having a predetermined rigidity and ductility and good workability.

In addition, the optical plate 550 is formed to correspond to the shape and size of the region in which the light source module 600 is located. That is, the optical plate 550 may have a shape that is inserted into the inside of the cover body 510.

The optical plate 550 presses the support protrusions 650 when the front cover 500 is coupled to the housing 200.

The front cover 500 may further include a sealing ring 560 to prevent moisture or foreign matter from entering the light source module 600 from the outside.

The sealing ring 560 seals the space where the light source module 600 is located and the outside. Specifically, the sealing ring 560 seals the space defined by the cover body 510 at the lower surface of the base plate 210 and the outside.

Further, the sealing ring 560 is coupled with the optical plate 550 to seal the inside and the outside of the optical plate 550.

Specifically, the sealing ring 560 is formed in a ring shape so as to be seated on the sealing ring seat portion 530.

The sealing ring 560 is fitted in the inner space with the rim of the optical plate 550. For example, the inner surface of the sealing ring 560 is recessed in the outer direction to form a ring groove 461, and the ring groove 461 is fitted with the rim of the optical plate 550.

Therefore, the area of the base plate 210 where the light source module 600 is positioned can be sealed to the outside by the sealing ring 560.

At this time, the front cover joining member is located outside the closed space formed by the sealing ring 560, thereby further preventing moisture or the like introduced from the front cover joining member from entering the light source module 600.

FIG. 14A is a cross-sectional view of another connection unit according to another embodiment of the present invention, and FIG. 14B is an internal view of a power connection hole according to another embodiment of the present invention.

The illumination device of another embodiment further includes a fastening guide as compared to the illumination device 10 of one embodiment.

Referring to FIG. 14, the fastening guide guides the coupling unit 400 and the housing 200 to each other.

That is, the fastening guides guide and assemble the connecting unit 400 and the housing 200 when they are coupled.

For example, the fastening guide includes a guide groove 212 and a guide protrusion 445.

The guide groove is formed in one of the power connection hole 211 or the connection body 410 and the guide protrusion is formed in the other one of the power connection hole 211 or the connection body 410.

14, the guide groove 212 is formed in the power connection hole 211 and the guide protrusion 445 is formed in the connection body 410. However, the present invention is not limited thereto.

The guide groove 212 provides a place where the guide protrusion 445 is mated and guided.

Specifically, the guide groove 212 is formed by recessing the inner surface of the power connection hole 211 to the outside.

The guide groove 212 has a first guide groove 212a whose upper portion is opened and the guide projection 445 is slidably engaged from top to bottom and a guide projection 445 which is slid in the first guide groove 212a, And a second guide groove 212b that is slidingly coupled.

The first guide groove 212a is open at the top and elongated at the top and bottom. That is, the first guide groove 212a guides the up and down movement of the connection body 410.

The second guide groove 212b communicates with the first guide groove 212a and is formed perpendicular to the first guide groove 212a to guide the lateral (rotational) movement of the guide protrusion 445. [

That is, the upward and downward movement of the guide protrusion 445 is restricted by the second guide groove 212b. Therefore, up-down flow is limited when the housing 200 and the connection body 410 are assembled together.

As another example, the guide groove (not shown) may be formed by recessing the outer surface of the insertion portion 440 inward.

Another example of the guide groove includes a first guide groove (not shown) in which the guide protrusion 445 is slidably coupled from below, and a second guide groove (not shown) in which the guide protrusion 445 slid in the first guide groove is laterally slidably engaged. (Not shown).

The guide protrusion 445 is formed in the connection body 410 and guided in the guide groove 212. As another example, the guide protrusion (not shown) may protrude from the inner surface of the power connection hole 211.

Specifically, the guide protrusion 445 protrudes outward from the outer surface of the insertion portion 440, and is guided by the guide groove 212 when the insertion portion 440 is inserted into the power connection hole 211.

Accordingly, when the insertion portion 440 is inserted into the power connection hole 211, the insertion portion 440 is first inserted from the top to the bottom by the fastening guide, and is rotated and fixed in one direction.

15 is a plan view of a lighting apparatus according to still another embodiment of the present invention.

In the embodiments of Fig. 15, there is a difference in the number of the light source modules 600 and the embodiment shown in Fig.

15 illustrates a structure in which various numbers of light source modules 600 are connected to the lighting device 10A around a power connection hole 211. In FIG.

In the lighting apparatus 10A of Fig. 15A, three light source modules 600a to 600c are arranged around a power connection hole 211. [

At this time, in order to emit uniform light in the illumination device 10, the internal angle between the light source modules 600 may be 120 degrees.

15B shows that four light source modules 600 are coupled.

In the lighting apparatus 10B of Fig. 15B, four light source modules 600a to 600d are arranged around a power connection hole 211. [

At this time, in order to emit uniform light in the illumination device 10, the internal angle between the light source modules 600 may be 90 degrees.

15C shows that eight light source modules 600 are coupled.

In the lighting apparatus 10C of Fig. 15C, eight light source modules 600a to 600h are arranged around the power connection hole 211. [

At this time, in order to emit uniform light in the illumination device 10, the internal angle between the light source modules 600 may be 45 degrees.

As described above, the lighting apparatus 10 of the embodiment can be easily realized by changing the number of the light source modules 600 to illuminate various power consumptions. In addition, even if a plurality of light source modules 600 are coupled, the light source module can be easily coupled to the power source connection hole 211, so that a sealing structure can be easily formed. So that the light source module 600 can supply power to the light source module 600.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

10: Lighting device
100: Power supply unit
200: Housing
300: Heatsink
400: connection unit
600: light source module

Claims (13)

A housing including a power connection hole;
At least one light source module disposed on a lower surface of the housing;
A power source unit which is located on the upper portion of the housing and supplies power to the light source module; And
And a connecting body for connecting the housing and the power unit and enclosing the cable hole and the cable hole through which the cable passes, wherein a part of the connecting body includes a connection unit inserted into the power connection hole,
The housing includes:
A base plate defining a space in which the light source module is located; And
And a plurality of second radiating fins disposed between the plurality of first radiating fins provided along the circumferential direction and the two adjacent first radiating fins disposed to surround the rim of the base plate,
Wherein external air flows through a space between two adjacent first radiating fins, a space between the first radiating fins and the second radiating fins, and a space between two adjacent second radiating fins. The method according to claim 1,
A first heat dissipating hole is provided between two adjacent first radiating fins,
A second heat dissipating hole is provided between two adjacent second radiating fins,
The first heat-dissipating hole is positioned to face the second heat-dissipating fin,
And the second heat dissipating hole is positioned to face the first heat dissipating fin. The method according to claim 1,
Wherein a flow path of the outside air is changed at least two times in the process of passing through the heat dissipation unit. The method according to claim 1,
Wherein the first radiating fins and the second radiating fins each extend from the base plate with different radii of curvature. The method according to claim 1,
Wherein the first radiating fin and the second radiating fin have the same width. The method according to claim 1,
And the second radiating fins protrude from the first radiating fins toward the power unit. The method according to claim 1,
Wherein the first radiating fin comprises:
A curved surface portion extending from the base plate and having a predetermined radius of curvature,
And a flat portion bent from the curved surface portion. 3. The method of claim 2,
And a rim portion forming an outer edge of the heat dissipation portion,
And the rim portion is bent in one direction. The method according to claim 1,
And a heat sink coupled to an upper surface of the base plate. 3. The method according to claim 1 or 2,
And a light source fixing unit for fixing the light source module to the connection unit,
The light source fixing unit includes:
At least one light source fixing groove formed in the connection body such that an inner surface forming the cable hole is recessed outwardly,
And a light source fixing protrusion formed on the light source module and cooperating with the light source fixing groove. 11. The method of claim 10,
The connecting body includes:
An insertion portion inserted into the power connection hole,
And a coupling portion overlapping the periphery of the power connection hole,
Wherein the light source fixing groove is formed in the insertion portion. 11. The method of claim 10,
Further comprising a front cover coupled to the housing to define a space in which the light source module is located and to transmit light generated in the light source module,
The light source module includes:
And a support protrusion supported by the front cover,
And the front cover presses the support protrusion when the front cover is engaged with the housing. The method according to claim 1,
The power unit
A power supply for generating a driving power,
And a casing in which the power supply unit is accommodated,
And a supporting member for fixing the casing to the outer space is coupled to the outer surface of the casing.

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