KR20150078209A - Lighting device - Google Patents

Abstract

According to an embodiment, a lighting device comprises: a light source unit generating light; a main reflector thermally connected with the light source unit and reflecting incident light from the light source unit to the front of an optical axis (Ax), where the light source unit is located inside; a heat sink thermally connected with the light source unit and the main reflector, separated from an outer surface of the main reflector at regular distance, and covering the main reflector; an air gap located between the outer surface of the main reflector and the heat sink; and an auxiliary reflector arranged on a lower area in the main reflector, and reflecting incident light from the light source unit to the front of the optical axis (Ax), wherein the main reflector contains a material having thermal conductivity and light reflexibility, and the auxiliary reflector has a reflective surface in a paraboloid shape having one focus.

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 swimming, 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 conducted 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 display devices, electric sign boards, and street lamps used outside the room.

A strict shape restriction condition such as further thinning of the lighting apparatus is required. In this case, for example, if a reflector having a single focal paraboloid with a basic shape of a reflecting surface is used, the thickness of the lamp can not be sufficiently reduced, and it is difficult to satisfy the shape constraint conditions such as the thinning of the above-

In addition, various studies are underway to effectively discharge the heat generated in the light source portion.

The illuminating device according to the embodiment can reduce the thickness of the illuminating device and effectively discharge heat generated in the light source portion.

The illumination device according to an embodiment includes a light source unit that generates light, a main reflector that includes the light source unit therein, is thermally connected to the light source unit, and reflects light incident from the light source unit forward of the optical axis Ax, And an air gap disposed between the outer surface of the main reflector and the heat sink, the air gap being located between the outer surface of the main reflector and the heat sink, the air gap being spaced a predetermined distance from the outer surface of the main reflector, And an auxiliary reflector disposed in a lower region of the main reflector and reflecting light incident from the light source portion forward of the optical axis Ax, wherein the main reflector includes a material having thermal conductivity and light reflectivity, The auxiliary reflector is characterized by having a paraboloid-shaped reflecting surface having one focal point. It shall be.

Since the main reflector has a shape that increases the contact area with the heat sink, and the upper area has a shape that reflects light generated in the light source part forward by the plurality of reflective cells toward the front of the optical axis, And the main reflector (bottom member) is increased, so that the heat generated in the light source unit can be effectively transmitted to the main reflector and the heat sink.

Further, since the auxiliary reflector is located in the lower region of the main reflector, the lower region of the main reflector has a shape increasing the contact area with the heat sink, and the light generated in the light source portion can not be reflected forward of the optical axis have.

Further, the contact area between the main reflector and the heat sink is increased, and the auxiliary reflector is used to prevent light loss.

Further, the convection circulation of the air contacting the illuminating device is promoted by the air hole formed in the heat sink and the air gap formed between the heat sink and the main reflector, thereby enhancing the heat transfer between the illuminating device and the outside air.

In addition, the embodiment includes a front reflector that shields the light source portion, so that the user can reduce the glare and the light source portion is not exposed to the outside, thereby improving the design aesthetics.

1 is a perspective view of a lighting apparatus according to an embodiment of the present invention,
Fig. 2 is an exploded perspective view of the lighting apparatus according to the embodiment of Fig. 1,
Fig. 3 is a partially exploded perspective view of the lighting apparatus according to the embodiment of Fig. 1,
FIG. 4 is a cross-sectional view of a lighting apparatus according to the embodiment of FIG. 1,
5 is a top plan view of the main reflector according to an embodiment,
6 is an explanatory view for explaining a main reflector according to the embodiment and a path through which light travels by the auxiliary reflector;
7 is a conceptual diagram illustrating heat transfer of a lighting apparatus according to an embodiment of the present invention,
8 is a cross-sectional view of a lighting apparatus according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Further, the angles and directions mentioned in the description of the structure of the embodiment are based on those shown in the drawings. In the description of the structures constituting the embodiments in the specification, reference points and positional relationships with respect to angles are not explicitly referred to, reference is made to the relevant drawings.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs. Also, commonly used predefined terms are not ideally or excessively interpreted unless explicitly defined otherwise.

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 an exploded perspective view of the lighting apparatus according to the embodiment of FIG. 1, FIG. 3 is a partially exploded perspective view of the lighting apparatus according to the embodiment of FIG. 4 is a cross-sectional view of the lighting apparatus according to the embodiment of FIG. 1, and FIG. 5 is a plan view of the main reflector viewed from above.

The X-axis and Y-axis directions of the plane of the illumination device 100 and the Z-axis direction of the optical axis Ax of the illumination device 100 are taken as the coordinate axes of X, Y and Z in the drawing.

1 to 5, a light source unit 130 is disposed on the optical axis Ax to generate light, and a light source unit 130 is disposed in the light source unit 130. Light incident from the light source unit 130 is transmitted to the front of the optical axis Ax A heat sink (not shown) which is thermally connected to the main reflector 120, the light source 130 and the main reflector 120 and is spaced apart from the outer surface of the main reflector 120 to surround the main reflector 120, An air gap 20 positioned between the outer surface of the main reflector 120 and the heat sink 180 and an air gap disposed between the outer surface of the main reflector 120 and the heat sink 180, And an auxiliary reflector 170 that reflects the light beam Ax forward.

The lighting apparatus 100 may further include a body 110 for supporting the heat sink 180.

The light source unit 130 may be supported by the main reflector 120.

Specifically, the light source unit 130 may be positioned on the bottom member 127 of the main reflector 120.

When the light source unit 130 is positioned at the bottom member 127 of the main reflector 120, the heat generated by the light source unit 130 is transmitted to the main reflector 120.

For example, the light source unit 130 includes a substrate 133 and a light emitting device 131 disposed on the substrate 133 and electrically connected to the substrate 133.

The substrate 133 is thermally connected to the bottom member 127 of the main reflector 120. Specifically, the substrate 133 is disposed on the upper surface of the bottom member 127.

The substrate 133 has a circular shape corresponding to the bottom member 127 of the main reflector 120, but is not limited thereto. For example, a polygonal shape, an elliptical shape, or the like.

The substrate 133 may be a printed circuit pattern on an insulator and may be, for example, a printed circuit board (PCB), a metal core PCB, a flexible PCB, a ceramic PCB, or the like .

Here, the light source 130 may be a chip on board (COB) that can directly bond an unpackaged LED chip on a printed circuit board. The COB contains ceramic materials to ensure heat resistance and insulation.

The upper surface (reference in FIG. 4) of the substrate 133 can be coated with a material capable of efficiently reflecting light. For example, the upper surface of the substrate 133 may be coated with a white or silver material.

The substrate 133 may be electrically connected to the light source 130 through a wire, but is not limited thereto.

One or more light emitting devices 131 may be disposed. When a plurality of light emitting devices 131 are disposed, each of the light emitting devices 131 may emit different colors or may have different color temperatures.

The light source unit 130 is located on the optical axis Ax to generate light. Here, the optical axis Ax means a main direction in which the light of the illumination device 100 is emitted. The light emitted from the lighting device 100 may be formed in a radial direction with respect to the optical axis Ax or in parallel with the optical axis Ax.

Specifically, the light source unit 130 is positioned at a predetermined position on the optical axis Ax. More specifically, when the light source unit 130 includes a plurality of light emitting devices 131, the center of the arrangement of the light emitting devices 131 may be defined as a light source point, and the light source point may be located on the optical axis Ax .

The body 110 receives heat generated from the heat sink 180 and dissipates heat. For this, the body 110 may be formed of a metal material or a resin material having a high heat emission efficiency, but the present invention is not limited thereto.

For example, the material of the body 110 may include at least one of aluminum (Al), nickel (Ni), copper (Cu), silver (Ag), and tin (Sn). The body 110 may be formed of a resin material such as polyphthalamide (PPA), silicon (Si), aluminum (Al), aluminum nitride (AlN), liquid crystal polymer (PSG) (PA9T), syndiotactic polystyrene (SPS), a metal material, sapphire (Al2O3), beryllium oxide (BeO), a printed circuit board (PCB), and ceramics. The body 110 may be formed by injection molding, etching, or the like, but is not limited thereto.

The body 110 provides a space in which the heat sink 180 and the main reflector 120 are positioned and may have various shapes in which a power source unit (not shown) is located.

Specifically, the body 110 supports the lower member 181 of the heat sink 180, and the body 110 may have a shape corresponding to the shape of the lower member 181 of the heat sink 180.

The body 110 has an accommodating portion (not shown) therein. The receiving portion may be formed by being recessed from one side of the body 110.

The housing portion of the body 110 can house the power source portion.

The power supply section may include a support substrate 155 and a plurality of components (not shown) mounted on the support substrate. The plurality of components (not shown) may include, for example, a DC converter for converting an AC power supplied from an external power source to a DC power source, a driving chip for controlling driving of the light source unit 130, An electrostatic discharge (ESD) protection device, and the like, but the present invention is not limited thereto.

The body 110 may support the main reflector 120 and the heat sink 180.

Specifically, the lower member 181 of the heat sink 180 is coupled to one surface of the body 110.

 A socket portion 150 is coupled to one surface of the body 110.

The socket unit 150 may be electrically connected to a power unit inside the body 110 and may have a shape coupled to an external power source.

Specifically, the socket portion 150 may have a connector 153 electrically connected to an external power source.

The heat sink 180 may be thermally connected to the light source unit 130 and the main reflector 120 and spaced apart from the outer surface of the main reflector 120 to surround the main reflector 120.

More specifically, the heat sink 180 includes a lower member 181 supporting at least the bottom member 127 of the main reflector 120, and a main reflector (not shown) connected in front of the optical axis Ax at the rim of the lower member 181 And a side wall 182 spaced apart from an outer surface of the main reflector 120 to surround the main reflector 120.

The lower member 181 supports at least the bottom member 127 of the main reflector 120. Therefore, the lower member 181 can have an area larger than at least the bottom member 127. [

The lower member 181 may be thermally connected to the light source 130 and the bottom member 127. Here, the term " thermally connected " will mean that the heat transfer between the parts is made efficient.

Specifically, the lower member 181 is brought into contact with the lower surface of the bottom member 127 of the main reflector 120, and the substrate 133 of the light source unit 130 is brought into contact with the upper surface of the bottom member 127.

The heat generated in the light source unit 130 is transmitted to the entire main reflector 120 and the lower member 181 of the heat sink 180 through the bottom member 127 of the main reflector 120.

The side wall 182 is connected to the front of the optical axis Ax at the rim of the lower member 181 and is spaced apart from the outer surface of the main reflector 120 so as to surround the main reflector 120.

Specifically, the side wall 182 can form a closed space around the optical axis Ax on a plane perpendicular to the optical axis Ax.

The side wall 182 dissipates the heat transferred from the lower member 181 to the outside.

The heat sink 180 may be formed of a material having high thermal conductivity. For example, the heat sink 180 may be formed of metal, and may be formed of aluminum (Al) according to an embodiment. The heat sink 180 may receive heat generated from the light source 130

Specifically, the heat sink 180 may have a shape having a large contact area with air.

An air gap 20 is formed between the side wall 182 of the heat sink 180 and the outer surface of the main reflector 120. The bottom member 181 of the heat sink 180 contacts the bottom member 127 of the main reflector 120 and the side wall 182 of the heat sink 180 and the outer surface of the main reflector 120 And the outer surface of the connecting member 125).

A plurality of air holes 183 may be formed in the side wall 182 to communicate the air gap 20 and the outside of the heat sink 180 and promote heat transfer through convection of the outside air.

The air hole 183 communicates with the outside of the heat sink 180 and the air gap 20 so that external air flows into the air gap 20.

The air holes 183 may be radially arranged on the side wall 182 of the heat sink 180 around the optical axis Ax.

The heat generated in the light source unit 130 is transmitted to the main reflector 120 contacting the light source unit 130 and the main reflector 120 is heat-exchanged with the external air by the air gap 20. The heat generated in the light source 130 is transmitted to the heat sink 180 contacted to the main reflector 120 and the heat transferred to the heat sink 180 passes through the air hole 183 Heat exchange occurs.

The main reflector 120 has a dish shape in which the light source unit 130 is positioned and reflects the light incident from the light source unit 130 and the front reflector 160 forward of the optical axis Ax.

The main reflector 120 may have an open shape substantially in the direction of the optical axis Ax.

Specifically, the main reflector 120 may extend radially in the X-Y axis direction perpendicular to the optical axis Ax and be inclined forward of the optical axis Ax.

The center of the main reflector 120 may be located on the optical axis Ax. That is, the main reflector 120 may be formed symmetrically with respect to the optical axis Ax.

More specifically, the main reflector 120 includes a bottom member 127 supporting the light source unit 130, a surface extending in the forward direction of the optical axis Ax from the rim of the bottom member 127 and perpendicular to the optical axis Ax A connecting member 125 which forms a closed space in the connecting member 125 and an extending member 121 which extends forward from the optical axis Ax and extends in the forward direction of the optical axis Ax, have.

The bottom member 127 supports the light source unit 130. Specifically, the bottom member 127 supports the substrate 133. The main reflector 120 and the light source unit 130 are thermally connected to each other, which means that the substrate 133 and the bottom member 127 are in contact with each other.

Preferably, the bottom member 127 may be disposed perpendicular to the optical axis Ax.

5, the bottom member 127 has a circular shape in a plane (XY-axis plane) perpendicular to the optical axis Ax and has a through hole (not shown) through which the hook 173 of the auxiliary reflector 170 passes, (129) is formed. The other end of the bottom member 127 is provided with a screw hole 128 through which a screw for screwing the substrate 133 and the bottom member 127 of the main reflector 120 to the bottom member 181 of the heat sink 180 May be formed.

The connecting member 125 extends forward of the optical axis Ax at the rim of the bottom member 127 and forms a closed space in a plane (X-Y axis plane) perpendicular to the optical axis Ax. The lower region opened toward the front of the optical axis Ax is formed by the bottom member 127 and the connecting member 125. The auxiliary reflector 170 is located in the above-described lower region.

Specifically, the connecting member 125 may be disposed on a circumference centered on the optical axis Ax. The shape of the connecting member 125 may have a cylindrical shape on a plane (X-Y axis plane) perpendicular to the optical axis Ax.

The extending member 121 may have a cross sectional area that extends forward of the optical axis Ax in the connecting member 125 and extends as it moves forward of the optical axis Ax.

Specifically, the expansion member 121 can form a closed space on a plane (X-Y axis plane) perpendicular to the optical axis Ax.

The boundary between the extending member 121 and the connecting member 125 is formed perpendicular to the optical axis Ax and the boundary between the extending member 121 and the connecting member 125 is formed on the optical axis Ax in front of the light source unit 130 Lt; / RTI > Here, vertical does not mean a perfect vertical of the mathematical meaning but it means vertical including an error in the engineering sense.

On the other hand, the expanding member 121 includes a reflection surface 123a having an arbitrary free-form surface 122 divided into a plurality of segments and having a reflection surface 123a for reflecting the incident light toward the front of the optical axis Ax, (123). This will be described later.

The main reflector 120 may comprise a material having thermal conductivity and light reflectivity. For example, the main reflector 120 may include at least one of Al, Ag, an Al alloy, and an Ag alloy. Here, the Al alloy is an alloy in which various metals are added to Al, and the Ag alloy is an alloy in which various metals are added to Ag.

More specifically, Al, Ag, Al alloy and Ag alloy are coated on the reflection surface formed on the inner surface of the expansion member 121 of the main reflector 120, and the remaining members of the main reflector 120 are made of a metal material Can be selected.

The auxiliary reflector 170 is disposed in the lower region of the main reflector 120 and reflects the light incident from the light source unit 130 toward the connecting member 125 of the main reflector 120 toward the front of the optical axis Ax.

Specifically, the auxiliary reflector 170 surrounds the optical axis Ax on a plane perpendicular to the optical axis Ax with respect to the optical axis Ax, opens in front of the optical axis Ax, A parabolic face portion 171 on which a light beam 177 is incident and a parabolic face portion 171 through which the bottom member 127 of the main reflector 120 and the heat sink 180 pass, 120 and a hook 173 for fixing to the heat sink 180.

The parabolic surface portion 171 may include a paraboloid-shaped reflective surface 175 having a single focal point. In addition, the parabolic face portion 171 may have a reflective surface 175 of a paraboloid of revolution shape.

Specifically, the paraboloid portion 171 is in the form of a paraboloid formed symmetrically about the optical axis Ax, and the focal point of the paraboloid can be located on the optical axis Ax. Therefore, the light incident from the light source unit 130 and the front reflector 160 can be uniformly collimated toward the front of the optical axis Ax.

The parabolic surface section 171 is opened in front of the optical axis Ax and an entrance hole 177 through which the light from the light source section 130 is incident is formed behind the optical axis Ax. The cross-sectional area can be expanded on the plane perpendicular to the optical axis Ax (XY-axis plane).

The center of the parabolic face 171 may be located on the optical axis Ax. That is, the parabolic face 171 may be formed symmetrically with respect to the optical axis Ax.

The hook 173 protrudes from the outer surface of the parabolic face 171 and can be inserted into and inserted into the through hole 129 formed in the bottom member 127 of the main reflector 120.

The auxiliary reflector 170 can be located in the space formed by the bottom member 127 and the connecting member 125. [

Specifically, the parabolic surface portion 171 may be provided to reflect light incident on the connection member 125 from the light source unit 130 toward the front of the optical axis Ax. Therefore, the parabolic face portion 171 can shield at least the connecting member 125. [

More specifically, the upper surface of the parabolic face 171 can be aligned with the boundary between the connecting member 125 and the extension.

The light incident on the connection member 125 of the light generated by the light source unit 130 is reflected by the auxiliary reflector 170 in front of the optical axis Ax and the light emitted from the light source unit 130, 121 are reflected toward the front of the optical axis Ax by the reflection cells of the expansion member 121. [

At this time, the light emitting device 131 is positioned inside the parabolic face 171 through the entrance hole 177, and the substrate 133 can shield the entrance hole 177.

6 is an explanatory view for explaining a main reflector according to the embodiment and a path through which light travels by the auxiliary reflector;

6, the expansion member 121 includes an arbitrary free-form surface 122 divided into a plurality of segments, a reflection surface 123a positioned on the segments and reflecting incident light forward of the optical axis Ax, And a reflection cell 123 having a reflective surface 123a.

The free-form surface 122 designates the basic shape of the reflective surface. The free-form surface 122 is a curved surface used for determining the shape of the reflective surface. The basic shape of the free-form surface 122 is a constant design such as satisfying the shape constraint without using a single paraboloid of revolution The curved surface satisfying the condition is selected as the free-form surface 122. [

The reflection cells 123 are allocated respective segments obtained by dividing the free-form surface 122, which is the basic shape, into a constant arrangement as shown in Figs. 5 and 6, and the reflection cells 123 are located in the segments.

The shape of each segment is constituted by a segment divided into segments of a constant pitch with respect to the mutually perpendicular X-axis direction and Y-axis direction so as to have the same rectangular shape as seen from the Z-axis direction.

The shape of the reflection cell 123 may be formed corresponding to the shape of the segment. Specifically, the shape of the reflection cells 123 may be formed to have a constant pitch with respect to the mutually perpendicular X-axis direction and Y-axis direction so as to have the same rectangular shape as seen from the Z-axis direction.

The reflective surface of the reflective cell 123 may have a shape that reflects the light incident from the light source unit 130 forward of the optical axis Ax.

Specifically, the reflecting surface 123a of the reflecting cell 123 may include any one of a flat surface, a convex surface, and a concave surface. When the shape of the reflecting surface 123a of the reflecting cell 123 is concave, light emitted from the lighting device 100 is improved in light focusing property, and when the reflecting surface 123a of the reflecting cell 123 is convex, The directing angle of the light emitted from the light source 100 is increased.

More specifically, the reflective surface 123a of the reflective cells 123 may form a paraboloid having different foci. The reflection surface of each reflection cell 123 reflects the light incident from the light source unit 130 toward the front of the optical axis Ax in consideration of the positional relationship between the reflection cell 123 and the light source unit 130, The focus can be set. Therefore, it is possible to design the reflector of various shapes and to make the lighting device 100 slimmer than using a parabolic shape with a single focus.

Therefore, the light L1 incident on the expansion member 121 from the light source unit 130 is reflected by the reflection surface 123a of the reflection cell 123 and is collimated to be parallel to the optical axis Ax.

The connecting member 125 forming the lower region of the main reflector 120 is formed in a cylindrical shape parallel to the optical axis Ax to increase the cross sectional area of the bottom member 127. [

The contact area of the heat sink 180 with the lower member 181 is increased so that the heat transmitted to the bottom member 127 can be efficiently transmitted to the lower member 181 of the heat sink 180 .

However, due to the shape of the connecting member 125, light incident from the light source unit 130 toward the connecting member 125 is not reflected toward the front of the optical axis Ax.

The auxiliary reflector 170 is formed to shield the connection member 125 so that the light L2 from the light source unit 130 toward the connection member 125 is reflected forward of the optical axis Ax.

7 is a conceptual diagram illustrating heat transfer of a lighting apparatus according to an embodiment of the present invention.

7, the heat generated in the light source unit 130 is transmitted from the bottom member 127 of the main reflector 120, which is in contact with the light source unit 130, to the connection member 125 and the extension member 121.

The heat generated in the light source unit 130 is transmitted to the heat sink 180 through the bottom member 127.

The heat transmitted to the side wall 182 and the expansion member 121 is sufficiently brought into contact with the outside air by the air gap 20 and heat exchange is performed with the outside air.

In addition, since the outside air is introduced into the air gap 20 by the air hole 183, more effective heat exchange becomes possible.

Of course, since the area of the bottom member 127 is increased by the connecting member 125, the amount of heat transmitted from the light source 130 to the bottom member 127 can be increased.

8 is a cross-sectional view of a lighting apparatus according to another embodiment of the present invention. Referring to FIG. 8, the lighting apparatus 100A according to the embodiment further includes a front reflector 160 as compared with the embodiment of FIG. There is a difference.

The front reflector 160 is positioned inside the main reflector 120 and is spaced forward from the optical axis Ax in the light source unit 130. The front reflector 160 is disposed on the main reflector 120 and the auxiliary reflector 120, (170).

The front reflector 160 may have a size to shield at least the light source unit 130. Specifically, the front reflector 160 is spaced apart from the light source unit 130 in the space inside the hemispherical main reflector 120 in the forward direction (Z-axis direction) of the optical axis Ax, and the light source unit 130 is positioned (XY-axis cross-section) that is larger than the area where the region is formed.

More specifically, the front reflector 160 may be spaced apart from the reflective surfaces of the main reflector 120 and the auxiliary reflector 170 by a predetermined distance to form a space through which light generated in the light source unit 130 is emitted.

The front reflector 160 may have a shape reflecting the light incident from the light source unit 130 toward the main reflector 120 (behind the optical axis Ax).

For example, when viewed from the front of the optical axis Ax, the front reflector 160 may have a shape corresponding to a region in which the light source unit 130 is located, in the plane shape of the X-Y axis. Preferably, the front reflector 160 may have a circular planar shape in the X-Y axis when viewed from the front of the optical axis Ax.

The front reflectors 151 and 152 may be formed behind the optical axis Ax of the front reflector 160 to reflect the light incident from the light source 130 toward the main reflector 120.

Specifically, the front reflector 160 may include front light reflecting surfaces 151 and 152 defined by rotating an arc of the plane with respect to the optical axis Ax (i.e., the rotating surface).

More specifically, the front light reflection surfaces 151 and 152 are in a conical shape having a vertex 153 directed to the rear (in the direction of the light source 130) of the optical axis Ax, and the conical surface thereof has a concave shape.

The vertex 153 of the front reflector 160 may be positioned on the optical axis Ax and the shape of the front reflector 160 may be formed symmetrically with respect to the optical axis Ax. Therefore, the light incident from the light source unit 130 can be uniformly reflected in the direction of the main reflector 120 (behind the optical axis Ax).

The front reflector 160 can reduce the glare of the user by covering the light source unit 130, and the light source unit 130 is not exposed to the outside, thereby improving the design aesthetic sense.

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.

100: Lighting equipment
110: Body
180: Heatsink
130:

Claims (14)

A light source for generating light;
A main reflector positioned inside the light source unit, thermally connected to the light source unit and reflecting the light incident from the light source unit forward of the optical axis Ax;
A heat sink which is thermally connected to the light source unit and the main reflector and is spaced apart from the outer surface of the main reflector so as to surround the main reflector;
An air gap positioned between the outer surface of the main reflector and the heat sink; And
And an auxiliary reflector which is disposed in a lower region of the main reflector and reflects the light incident from the light source portion forward of the optical axis Ax,
The main reflector includes:
Comprising a material having thermal conductivity and light reflectivity,
Wherein the auxiliary reflector has a reflective surface of a paraboloid shape having one focal point. The method according to claim 1,
The main reflector includes:
A bottom member for supporting the light source unit;
A connecting member extending forward from the rim of the bottom member in the direction of the optical axis Ax and forming a closed space in a plane perpendicular to the optical axis Ax;
And an extension member having a cross-sectional area extending forward of the optical axis Ax and extending as the optical axis Ax extends forward,
Wherein the connecting member comprises a cylindrical shape. 3. The method of claim 2,
The expansion member of the main reflector may include:
And a reflective cell having an arbitrary free-form surface divided into a plurality of segments and having a reflecting surface positioned in the segments and reflecting the incident light forward of the optical axis Ax. The method of claim 3,
And the center of the main reflector is located on the optical axis (Ax). 5. The method of claim 4,
Wherein the main reflector comprises at least one of Al, Ag, Al alloy and Ag alloy. The method of claim 3,
Wherein the auxiliary reflector comprises:
An entrance hole is formed in the front of the optical axis Ax and a light entrance hole in which the light of the light source section is incident is formed behind the optical axis Ax in a plane perpendicular to the optical axis Ax with respect to the optical axis Ax The parabolic portion,
And a hook for fixing the parabolic face portion to the main reflector and the heat sink through the bottom member of the main reflector and the heat sink. The method according to claim 6,
Wherein the auxiliary reflector comprises:
The bottom member and the connecting member,
And an upper surface of the parabolic face portion coincides with a boundary between the connecting member and the extending portion. 8. The method of claim 7,
The light source unit includes:
A light emitting element located inside the parabolic face portion through the entrance hole,
And a substrate which is electrically connected to the light emitting element and shields the entrance hole. 9. The method of claim 8,
Wherein one surface of the substrate is thermally connected to a bottom member of the main reflector. 9. The method of claim 8,
The heat sink
A lower member supporting at least the bottom member of the main reflector,
And a side wall connected to the front of the optical axis Ax at a rim of the lower member and spaced apart from an outer surface of the main reflector to surround the main reflector,
Wherein the lower member is thermally connected to the substrate and a bottom member of the main reflector. 11. The method of claim 10,
Wherein the side walls are provided with a plurality of air holes communicating the air gap and the outside of the heat sink and promoting heat transfer through convection of outside air. 10. The method of claim 9,
Further comprising a front reflector positioned inside the main reflector and positioned forward of the optical axis Ax in the light source portion and reflecting part of the light generated in the light source portion toward the main reflector and the auxiliary reflector. 13. The method of claim 12,
The front reflector includes:
Wherein the light source unit has a larger cross-sectional area than a region where the light source unit is located. 11. The method of claim 10,
And the boundary between the extending member and the connecting member is located on the optical axis Ax ahead of the light source unit.

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