KR20200065859A - Lighting apparatus for mounting drone - Google Patents

Abstract

Provided is a lighting device mounted on a drone (10) to provide illumination light, which can be reduced in size and weight while providing concentrated white light with high luminance. According to the present invention, the lighting device comprises an illumination light module (100) including: a blue light source unit (laser diode, 111) supported by a light source mount (116) to be fixedly installed in the lighting device, and emitting blue light to one side as driving power is applied; a phosphor jig (112) disposed in one direction of the blue light source unit (111) and having a through-hole (113) open to the front and rear at a position corresponding to the blue light source unit (111); a phosphor (114) disposed at the position of the through-hole (113) in the phosphor jig (112) and excited by blue light incident through the through-hole (113) to emit white light; and a light distribution lens (115) disposed in another direction of the phosphor jig (112) to face the phosphor (114) to adjust the distribution of the white light emitted. The blue light source unit (111) and the phosphor (114) are spaced apart by a focal length (L) at which the blue light emitted from the blue light source unit (111) can be concentrated on the phosphor (114).

Description

LIGHTING APPARATUS FOR MOUNTING DRONE}

The present invention relates to a drone-mounted lighting device mounted on a drone, and more specifically, a blue light source unit that generates heat while emitting blue light and a phosphor that emits white light by being excited by the blue light are spaced apart at a certain distance from each other and at the blue light source unit. The present invention relates to a drone-mounted lighting device capable of miniaturizing and lightening a lighting device while providing white light concentrated at a high luminance by allowing the emitted blue light to be concentrated in a phosphor with an optical system.

1 shows the construction of a drone for a lighting module with a conventional LED lamp. Referring to the drawings, it is possible to fly up, down, left, and right through a plurality of rotating propellers, and is equipped with LED lamps 410, 420, and 430 that irradiate light sources upward or downward to be used as a lighting fixture in the work area.

In addition, the main body 100 is equipped with an upper LED lamp 410 for irradiating a light source upward to the upper surface, a lower LED module 420 for irradiating a light source downward is mounted on the lower surface, and a side LED module 430 is provided at the side. It was equipped to provide lighting in all directions.

Usually, the LED terminal mounted on the LED lamp or LED module is integrally formed so that the light source and the phosphor are in close contact, so that the light emitted from the light source cannot be concentrated on the phosphor, so a plurality of LED terminals are focused in a bundle to provide the required amount of illumination light. It was provided to provide. When such a LED lamp or LED module is mounted on a drone, the space for mounting other ancillary equipment such as a camera or a landing device in addition to the lighting becomes large as well as the light increases, and the weight increases, which increases the weight of the drone that requires rotating the propeller with limited battery capacity. It served as a problem that drastically reduced flight time.

Published Patent Publication No. 10-2017-0093579 (August 16, 2017), a drone for a lighting module with an LED lamp.

The present invention was created to solve the above-described problem, and an object of the present invention is to separate a blue light source unit that emits a large amount of heat while emitting blue light and a phosphor that is excited by the blue light to emit white light and space a certain distance from each other. Drone-mounted lighting device capable of miniaturizing and reducing the weight of the lighting device while preventing high heat from the blue light source from being transmitted to the phosphor and at the same time allowing the blue light emitted from the blue light source to be collected by the optical system into the phosphor, thereby providing white light focused at a high luminance. In providing.

Another object of the present invention is to provide a drone-mounted lighting device consisting of a structure capable of efficiently cooling the driving heat generated while providing lighting by introducing flying air generated according to the flight of the drone.

The drone-mounted lighting device according to the present invention for achieving the above object is mounted in the drone 10, the drone-mounted lighting device for providing illumination, supported by the light source mount 116, the drone-mounted lighting The blue light source unit 111 that is fixedly mounted in the device and emits blue light to one side according to the applied driving power, and is disposed at a predetermined distance apart in one direction of the blue light source unit 111 and corresponds to the blue light source unit 111 The through hole 113 is formed between the phosphor jig 112 and the blue light source unit 111 and the phosphor jig 112 that are formed in the through hole 113 that is opened in the front and rear directions. ), and the phosphor 114 which is disposed at the position of the through hole 113 in the phosphor jig 112 and is excited by blue light incident through the through hole 113 to emit white light. , It may include an illumination light module 110 including a light distribution lens 115 that is disposed on one side of the phosphor jig 112 so as to face the phosphor 114 to control the light distribution of the emitted white light.

Here, the blue light source unit 111 and the phosphor 114, the size of the phosphor 114, the diameter of the through hole 113, the focal length (L) set according to the current size applied to the blue light source unit 111 (L ).

In addition, the light source mount 116 is made of a thermally conductive material, and is mounted so that one side is in close contact with the other side of the light source mount 116, and a plurality of heat sinks 121 are provided on the other side to be transmitted from the light source mount 116. A heat sink 120 that discharges heat to the outside; The illumination light module 110 is disposed in a form surrounding the lighting light module 110 to emit the white light of the illumination light module 110 to the outside and is formed and is formed of a relatively larger size than the illumination light module 110, the illumination light module A housing 130 forming a space 131 between the side and the inner side of the 110; And a front frame disposed between an end edge of the illumination light module 110 and an open one side edge of the housing 130, and having a plurality of outside air inlet holes 141 formed therein to introduce outside air into the space 131. 140); may further include.

In addition, each heat sink 121 of the heat sink 120 may be formed to extend from one side to the other.

In addition, the rear housing 150 is disposed in a form surrounding the heat sink 120 and has a relatively larger size than the heat sink 120 to form a space between the side and inner surfaces of the heat sink 120; It may further include.

In addition, the front frame 140 may be formed with a plurality of ribs 142 spaced apart along the extended length, and the outside air inlet hole 141 may be formed between each rib 142.

In addition, as the front frame 140, each rib 142 is disposed inclined in the same direction, the outside air may be introduced in a diagonal direction through each of the outside air inlet holes 141.

Meanwhile, a side vent hole 143 may be formed along the side circumference at a position corresponding to the light source mount 116 on the housing 130.

According to the lighting apparatus for mounting a drone according to the present invention, in the case of the illumination light module 110 mounted on the drone 10 and providing illumination, it is supported by the light source mount 116 and fixedly mounted in the lighting apparatus for mounting the drone and applied The blue light source unit 111 that emits blue light to one side according to the driving power to be provided, and is arranged to be spaced a predetermined distance in one direction of the blue light source unit 111 and penetrates the front and rear openings at positions corresponding to the blue light source unit 111. An optical system that collects the blue light emitted from the blue light source unit 111 and the blue light source unit 111 between the blue light source unit 111 and the phosphor jig 112 and the phosphor jig 112 on which the ball 113 is formed ( 119), a phosphor 114 disposed at the position of the through hole 113 in the phosphor jig 112 and excited by blue light incident through the through hole 113 to emit white light, and the phosphor 114 The blue light source 111 and the blue light emitted while emitting blue light, such as a light distribution lens 115 that controls light distribution of white light that is disposed on one side of the phosphor jig 112 so as to face the light, is excited. The phosphors emitting white light are spaced apart from each other by a certain distance, and the blue light emitted from the blue light source 111 is collected by the optical system 119 into the phosphor 114, while providing high brightness and concentrated white light. The device can be miniaturized and lightweight.

In addition, the light source mount 116 is made of a thermally conductive material, the heat sink 120 is mounted so that one side is in close contact with the other side of the light source mount 116 is provided with a plurality of heat sink 121 on the other side of the light source mount The housing 130, which dissipates heat transmitted from 116 and is disposed in a form surrounding the illumination light module 110, has a lighting hole on one side for emitting white light from the illumination light module 110 to the outside. It is formed and has a relatively larger size than the illumination light module 110 to form a space portion 131 between the side and inner surfaces of the illumination light module 110, the edge of the illumination light module 110 and the housing ( The front frame 140 disposed between the opened one side rim of 130 is a plurality of air inlet holes 141 are formed, such as to introduce the outside air into the space portion 131, the flight that occurs according to the flight of the drone It is possible to efficiently cool the driving heat generated by introducing the wind into the interior and providing lighting.

1 is a perspective view showing the configuration of a drone for a lighting module with a conventional LED lamp,
Figure 2 is a perspective view showing a drone mounting lighting device according to a preferred embodiment of the present invention mounted on the drone,
3 is a perspective view showing the configuration of a lighting device for mounting a drone equipped with a plurality of illumination light modules according to a preferred embodiment of the present invention,
4 and 5 are side and separate perspective views showing the configuration of the illumination light module according to a preferred embodiment of the present invention,
6 is a schematic view showing a state in which the blue light source portion and the phosphor according to a preferred embodiment of the present invention are separated by a focal length,
Figure 7 is a perspective view showing the configuration of the side vents and rear housing according to a preferred embodiment of the present invention,
Figure 8 is a side cross-sectional view showing the configuration of a lighting device for mounting a drone according to a preferred embodiment of the present invention,
9 is a perspective view showing the configuration of a rib according to a preferred embodiment of the present invention,
10 is a perspective view showing a configuration in which the ribs are inclined according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be interpreted as being limited to ordinary or dictionary meanings, and the inventor appropriately explains the concept of terms in order to explain his or her invention in the best way. Based on the principle of being able to be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the configuration shown in the embodiments and drawings described in this specification is only one of the most preferred embodiments of the present invention and does not represent all of the technical spirit of the present invention, and thus can replace them at the time of application. It should be understood that there may be equivalents and variations.

The drone-mounted lighting device 100 according to a preferred embodiment of the present invention separates the blue light source unit 111 that is heated while emitting blue light and the phosphor 114 that is excited by the blue light and emits white light at a certain distance from each other. The blue light emitted from the blue light source unit 111 can be focused on the phosphor 114 by the optical system 119 to provide white light concentrated at a high luminance while being capable of miniaturizing and lightening the lighting device, as shown in FIG. 2. Likewise, it can be mounted on the drone 10 to provide illumination light. Here, as shown in the drawing, it may be installed to be mounted on the drone 10 and mounted together on the gimbal 11 on which the camera 12 is mounted.

3 to 6 shows the configuration of the illumination light module 110 mounted inside the lighting device 100 for mounting the drone. Referring to the drawings, the illumination light module 110 includes a blue light source unit 111, a phosphor jig 112, an optical system 119, a phosphor 114, and a light distribution lens 115.

First, the blue light source unit 111 is a light emitting means for providing a light source necessary to emit illumination light, and is supported by the light source mount 116 and fixedly mounted in the lighting device 100 for mounting a drone. Radiates as A blue LED and a blue laser diode may be used as the blue light source 111.

The phosphor jig 112 is a jig for supporting the phosphor 114 to be fixedly disposed in the light emission direction of the blue light source unit 111 and is arranged to be spaced a predetermined distance in one direction of the blue light source unit 111 and the blue light source unit 111 ), a through hole 113 opened in the front and rear direction is formed.

The optical system 119 is an optical means for concentrating the blue light from the blue light source unit 111 to the phosphor 114 and is disposed between the blue light source unit 111 and the phosphor jig 112 to receive blue light emitted from the blue light source unit 111. It is concentrated in the through hole (113). As the optical system 119, a convex lens or a spherical ball lens can be used.

The phosphor 114 is disposed at the position of the through hole 113 in the phosphor jig 112 and is excited by the blue light incident through the through hole 113 to emit white light. Here, it may be made of a yellow fluorescent material to convert the blue light into white light.

In addition, in FIG. 6, it is preferable that the blue light source part 111 and the phosphor 114 are spaced apart at a focal length L at which blue light emitted from the blue light source part 111 can be concentrated on the phosphor 114. In particular, the blue light source unit 111 and the phosphor 114, the focal length (L) set according to the size of the phosphor 114, the diameter of the through hole 113, the current size applied to the blue light source unit 111 By being spaced apart, the optimal amount of white light can be emitted to the illumination area by amplifying the limited light amount of the blue light source unit 111 to the maximum.

The light distribution lens 115 is disposed on one side of the phosphor jig 112 so as to face the phosphor 114 to control the light distribution of the emitted white light. To this end, the white light emitted by the blue light concentrated on the phosphor 114 is required. Diffuse transmission to have a luminous area.

Therefore, the inclination angle of the side inclined surface may be changed according to the required light distribution range of the white light, and a reflective member for reflecting light may be disposed on the side inclined surface to increase light efficiency and control light distribution as shown in FIG. 4. If necessary for the concave or convex condensing lens 117 may be mounted.

As described above, in the case of the illumination light module 110 mounted on the drone 10 and providing illumination, it is supported by the light source mount 116 and fixedly mounted in the lighting apparatus for mounting the drone and receives blue light according to the applied driving power. The blue light source portion 111 and the blue light source portion 111 is arranged to be spaced a predetermined distance apart in one direction in the direction corresponding to the blue light source portion 111, the front and rear opening through the hole 113 is formed a fluorescent substance jig The optical system 119 disposed between the blue light source unit 111 and the phosphor jig 112 to collect the blue light emitted from the blue light source unit 111 into the through hole 113, and the phosphor jig (112) The phosphor 114 disposed at the position of the through hole 113 within the 112 and excited by blue light incident through the through hole 113 to emit white light, and the phosphor jig 112 to face the phosphor 114 ), a blue light source unit 111 that generates heat while emitting blue light, and a phosphor 114 that is excited by the blue light and emits white light, as it includes a light distribution lens 115 that is disposed in one direction to control the light distribution of white light emitted. ) Spaced apart from each other by a certain distance, and the blue light emitted from the blue light source 111 can be collected by the optical system 119 into the phosphor 114, thereby providing a white light focused at a high brightness while miniaturizing and lightening the lighting device. .

On the other hand, the lighting device 100 for mounting a drone according to a preferred embodiment of the present invention further includes a heat sink 120, a housing 130 and a front frame 140.

Specifically, as shown in FIGS. 7 and 8, the light source mount 116 is made of a thermally conductive material, and the heat sink 120 is mounted so that one side is in close contact with the other side of the light source mount 116. On the side, a plurality of heat sinks 121 are provided to dissipate heat transferred from the light source mount 116 to the outside, and the housing 130 disposed in a form surrounding the illumination light module 110 has an illumination light module 110 on one side. ) Is formed by opening a light hole for emitting white light to the outside and has a relatively larger size than the light module 110 to form a space 131 between the side and inner surface of the light module 110, The front frame 140 disposed between the end edge of the illumination light module 110 and the opened one side edge of the housing 130 is formed with a plurality of outside air inlet holes 141 to form outside air to the space 131. As with the inflow, it is possible to efficiently cool the driving heat generated while providing lighting by introducing the flying wind generated according to the flight of the drone.

Here, the heat sink 120 is formed by extending in the airflow direction flowing into the air through the outside air inlet hole 141, as each heat sink 121 is formed extending from one side to the other side, the contact area and contact with air Cooling efficiency can be maximized by increasing the time.

In addition, referring to FIGS. 7 and 10, the rear housing 150 disposed in a form surrounding the heat sink 120 has a size larger than that of the heat sink 120 and the side portion of the heat sink 120. By forming a space between the inner surfaces, it is possible to further increase the cooling efficiency by the heat sink 121 by guiding the outside air flowing into the space to flow along each heat sink 121 of the heat sink 120.

In addition, as shown in FIGS. 8 and 9, the front frame 140 is formed with a plurality of ribs 142 spaced apart along an extended length, and an air inlet hole 141 is formed between each rib 142. When the front frame 140 is disposed in the forward direction toward the flight direction of the drone 10, the flying wind generated according to the flight of the drone 10 is distributed through each rib 142 so that each external air inflow hole ( 141), it is possible to reduce the air resistance by the front frame 140.

And, as shown in Figure 10, the front frame 140, each rib 142 is arranged in an inclined direction in the same direction is made of a structure in which the outside air flows in a diagonal direction through each outside air inlet hole 141, the outside air As the outside air flows through the inflow hole 141, the contact time with each heat sink 121 can be increased.

In addition, as shown in FIGS. 7, 8 and 10, a side vent hole 143 is formed along the lateral circumference and formed at the position corresponding to the light source mount 116 on the housing 130 to form the blue color. The light source unit 111 is mounted to supply the outside air directly to the light source mount 116 that generates heat with high heat, thereby further increasing the cooling efficiency by the outside air.

The lateral ventilation holes 143 are provided with the outside air introduced into the outside air inlet hole 141 of the front frame 140 when the drone-mounted lighting device 100 is directed forward toward the flight direction of the drone 10. It functions as a passage through which the light source mount 116 and the phosphor jig 112 are cooled while passing through the space portion 131 of 130, and when the lighting device 100 for mounting a drone is directed downward The air flowing through the outside air inlet hole 141 by the driving heat of the mount 116 functions as a passage through which the air is discharged upward.

As described above, although the present invention has been described by a limited number of embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following will be described by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims to be described.

10... drone 100... drone mounting lighting device
110...Lighting module 111...Blue light source
112...Phosphor jig 113...Through hole
114...Phosphor 115...Light distribution lens
120...heat sink 121...heat sink
130...Housing 140...Front frame
141...outflow hole 142...rib
143...lateral vent 150...rear housing

Claims (9)

In the drone mounting lighting device that is mounted on the drone (10) to provide illumination light,
A blue light source unit 111 supported by the light source mount 116 and fixedly mounted in the drone mounting lighting device and emitting blue light to one side according to the applied driving power;
Phosphor jig 112 which is arranged to be spaced a certain distance in one direction of the blue light source 111 and corresponding to the blue light source 111 is formed with a through hole 113 opened in the front and rear,
An optical system 119 disposed between the blue light source unit 111 and the phosphor jig 112 to collect blue light emitted from the blue light source unit 111 into the through hole 113,
A phosphor 114 disposed at the position of the through hole 113 in the phosphor jig 112 and excited by blue light incident through the through hole 113 to emit white light, and
Including the illumination light module 110 including a light distribution lens 115 disposed in one direction of the phosphor jig 112 so as to face the phosphor 114 to control the light distribution of the emitted white light;
Drone-mounted lighting device.
According to claim 1,
The blue light source unit 111 and the phosphor 114,
Drone-mounted lighting device, characterized in that arranged at a set distance according to the size of the phosphor 114, the diameter of the through hole 113, the current size applied to the blue light source 111.
According to claim 1,
The light source mount 116 is made of a thermally conductive material,
A heat sink 120 which is mounted so that one side is in close contact with the other side of the light source mount 116 and is provided with a plurality of heat sinks 121 on the other side to discharge heat transmitted from the light source mount 116 to the outside; And
The illumination light module 110 is disposed in a form surrounding the lighting light module 110 for emitting white light to the outside, and is formed by opening a light bulb and is made of a relatively larger size than the lighting light module 110, the lighting light module Drone mounting lighting device comprising a; housing 130 that forms a space 131 between the side and the inner surface of the (110).
According to claim 3,
The front frame 140 is disposed between the end edge of the illumination light module 110 and the opened one side edge of the housing 130, and a plurality of outside air inlet holes 141 are formed to introduce outside air into the space 131. ); Drone mounted lighting device comprising a.
The method of claim 4,
The heat sink 120 is a drone mounting lighting device, characterized in that each heat sink 121 is formed extending from one side to the other.
The method of claim 5,
The rear housing 150 is arranged in a form surrounding the heat sink 120 and has a larger size than the heat sink 120 to form a space between the side and inner surfaces of the heat sink 120. Drone mounted lighting device comprising a.
The method of claim 5,
The front frame 140,
Drone-mounted lighting device, characterized in that a plurality of ribs 142 are spaced apart along the extended length, the outside air inlet hole 141 is formed between each rib (142).
The method of claim 7,
The front frame 140,
Drone-mounted lighting device, characterized in that each rib 142 is disposed obliquely in the same direction, and the outside air flows in a diagonal direction through each outside air inlet hole 141.
The method according to any one of claims 3 to 8,
A lighting device for mounting a drone, characterized in that a side vent hole (143) is formed along a lateral circumference at a position corresponding to the light source mount (116) on the housing (130).

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