KR101800635B1 - A device for lighting indoor space - Google Patents

Abstract

The present invention realizes a long distance irradiation by implementing the characteristics of a point source of a laser beam, conversion to white light using a phosphor, and minimization of beam loss using an optical system, and a blue laser diode and a phosphor An industrial lighting apparatus using a blue laser diode and a phosphor according to the present invention includes a blue laser generator having a plurality of blue laser diodes radially arranged to irradiate a blue laser beam forward; An installation body for providing a space for installing the plurality of blue laser diodes so that a plurality of laser beams irradiated from the plurality of blue laser diodes are collected at a specified forward position; A power socket having a structure coupled to a rear portion of the installation body and coupled to a bulb installation device capable of coupling an incandescent bulb, and connected to the bulb installation device to supply power to the blue laser generation portion; A light focusing unit installed in front of the blue laser diode and focusing the laser beams emitted from the blue laser diode into parallel light and condensing the laser beams at a specific point; A phosphor unit installed at a specific point forward of the light path changing unit and converting the blue laser condensed by the light focusing unit into white light; And a white light diffusing unit disposed at the rear of the phosphor unit and irradiating the white light converted by the phosphor unit in the front direction of the phosphor unit.

Description

TECHNICAL FIELD [0001] The present invention relates to an industrial lighting apparatus using a blue laser diode and a phosphor.

The present invention relates to an industrial lighting apparatus, and more particularly, to an industrial lighting apparatus, which is capable of long distance irradiation by realizing a point light source characteristic of a laser beam and converting it into white light using a phosphor and minimizing beam loss using an optical system, And more particularly, to an industrial lighting apparatus using a blue laser diode and a phosphor which are particularly effective for factory lighting, stage lighting, athletic field lighting, and the like, which can vary the irradiation range and are three times brighter than conventional lighting power consumption .

Regardless of all application areas of lighting, the problems that conventional lighting systems have not solved are a few differences in the lighting field, but in general, the first is to minimize the power consumption, the second is to efficiently use the total light output from the lamp And third, the high-intensity lighting system does not solve the weight and portable power supply system.

Conventional factory lighting devices generally use metal halide lamps because they are large in power consumption and the length of the lighting device does not make full use of the ceiling height of the factory. There are fatal inconveniences such as points.

The object of the present invention is to solve the problems of the present invention by providing a point light source characteristic of a laser beam, converting it into white light using a phosphor, minimizing beam loss using an optical system, and the like. Which is variable in size and which is three times brighter than conventional lighting power consumption, is an industrial lighting apparatus using a blue laser diode and a phosphor, which are particularly effective for plant lighting, stage lighting, and playground lighting.

According to an aspect of the present invention, there is provided an industrial lighting apparatus using a blue laser diode and a phosphor, including: a blue laser generator having a plurality of blue laser diodes radially arranged to forward a blue laser beam; An installation body for providing a space for installing the plurality of blue laser diodes so that a plurality of laser beams irradiated from the plurality of blue laser diodes are collected at a specified forward position; A power socket having a structure coupled to a rear portion of the installation body and coupled to a bulb installation device capable of coupling an incandescent bulb, and connected to the bulb installation device to supply power to the blue laser generation portion; A light focusing unit installed in front of the blue laser diode and focusing the laser beams emitted from the blue laser diode into parallel light and condensing the laser beams at a specific point; A phosphor unit installed at a specific point forward of the light path changing unit and converting the blue laser condensed by the light focusing unit into white light; And a white light diffusing unit disposed at the rear of the phosphor unit and irradiating the white light converted by the phosphor unit in the front direction of the phosphor unit.

In the present invention, it is preferable that the light focusing unit is made of an aspherical lens.

In the present invention, it is preferable that the phosphor portion is a crystal type phosphor.

The industrial lighting apparatus using the laser and the phosphor according to the present invention may further include a phosphor driving unit coupled to a rear end of the phosphor unit and driving the phosphor unit forward and backward; And a phosphor mounting part coupled to the phosphor driving part to fix the phosphor part and the phosphor driving part to the white light diffusing part.

Further, in the present invention, the phosphor mounting portion may include: a circular protective glass for blocking an opening of the white light diffusing portion; A metal band formed along an inner peripheral surface of the protective glass; A cathode terminal connected to one end of the metal strip and connected to an anode of a power supply line supplied to the laser diode; And a negative electrode terminal coupled to the other end of the metal strip and connected to the negative electrode of the power line supplied to the laser diode.

Further, the industrial lighting apparatus using the laser and the phosphor according to the present invention may further comprise: an outer cover which is fastened with the protective glass interposed in the installation groove of the white light diffusion portion; And a sealing gasket provided between the outer cover and the white light diffusing unit to seal the space inside the white light diffusing unit.

According to the present invention, it is possible to perform a long distance irradiation by implementing the characteristics of a point source of a laser beam, conversion to white light using a phosphor, and minimization of beam loss using an optical system, and the irradiation range can be varied by adjusting fine- The illumination device is three times brighter than the lighting power consumption, and is particularly effective for factory, stage lighting, and athletic field lighting with high ceilings in the workplace.

1 is a view showing a configuration of an industrial lighting apparatus according to an embodiment of the present invention.
2 is a view showing an optical path of an industrial lighting apparatus according to an embodiment of the present invention.
3 is a view showing a structure of a protective glass according to an embodiment of the present invention.

Hereinafter, a specific embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1, an industrial lighting apparatus 100 using a blue laser diode and a phosphor according to an embodiment of the present invention includes a blue laser generating unit 110, a main body 120, a power socket 130, A light source 140, a phosphor unit 150, and a white light diffusion unit 160.

First, as shown in FIG. 1, the blue laser generation unit 110 is a component in which a plurality of blue laser diodes radiating a blue laser beam forward are disposed. That is, as shown in FIG. 1, the plurality of blue laser diodes 110 are arranged such that each of the laser beams is irradiated toward one point in the forward direction as shown in FIG. 2, The laser diodes can be used as they are commonly known laser diodes.

1 and 2, the mounting body 120 is a component for providing a mounting position and a space of the plurality of blue laser diodes 110. The plurality of blue laser diodes 110 are stably installed such that a plurality of laser beams irradiated from the plurality of blue laser diodes 110 are gathered at specific points forward by the installation body 120. The installation body 120 may further include a cooling unit (not shown) for cooling the blue laser diode 110.

1 and 2, the power socket 130 is coupled to a rear portion of the installation body 120 and is coupled to a bulb installation device capable of coupling an incandescent bulb. Accordingly, the power socket 130 has a spiral structure so as to be coupled to the bulb installation place, and is connected to the bulb installation device to supply power to the blue laser generation unit 110.

1 and 2, the light focusing unit 140 is a component installed in front of the blue laser diode 110 and collecting the laser beam irradiated from the laser diode as parallel light .

The output beam of the laser diode 110 is diffused and output at a certain angle. It is necessary to use the light converging unit 140 so that the laser beam becomes a parallel beam because it is disadvantageous in irradiation of a surface light source having a strong directivity. Accordingly, the light focusing unit 140 may be an aspherical lens.

As shown in FIG. 1, the phosphor unit 150 is installed at a specific point in front of the light focusing unit 140, and converts the blue laser beam into white light. Since the laser beam used in this embodiment is focused and irradiated to the phosphor 150, the organic fluorescent substance, which does not guarantee the heat resistance performance of the phosphor, burns within a few seconds. Therefore, in the present embodiment, it is preferable to use a crystal-type phosphor excellent in heat resistance.

1 and 2, the white light diffusing unit 160 is provided as a photoreceptor on the rear side of the phosphor unit 150, and the white light converted from the phosphor unit 150 is emitted toward the front of the phosphor unit 150 Direction. At this time, the irradiation range of the white light diffusing unit 160 can be adjusted by adjusting the distance between the parabolic surface of the white light diffusing unit 160 and the phosphor unit 150.

Therefore, it is preferable that the industrial lighting apparatus 100 according to the present embodiment further includes a phosphor driving unit 170 and a phosphor mounting unit 180, as shown in FIGS. When the focal point of the white light diffusing unit 160 and the phosphor 150 are at the same position, the white light in the phosphor may be diverged as parallel light, and the irradiation range may be narrowed. Therefore, a mechanical structure capable of changing the focal length or varying the position of the phosphor is required.

1, the phosphor driving unit 170 is coupled to the rear end of the phosphor unit 150 and drives the phosphor unit 150 forward and backward. For example, the phosphor driving part 170 may be coupled to a rear end of the phosphor, and may have a structure for driving the phosphor part 150 in the forward and backward directions while rotating along the screw structure with respect to the phosphor mounting part 180.

1, the phosphor driving unit 170 is coupled to the phosphor driving unit 170. The phosphor driving unit 170 and the phosphor driving unit 170 are connected to the white light emitting unit 160, As shown in Fig. Therefore, the phosphor mounting part 180 preferably has a spiral structure that can be fastened to the front end of the white light diffusing part 160, and is made of a material through which white light can pass.

3, the phosphor mounting portion 180 includes a protective glass 181, a metal strip 182, a positive electrode terminal 183, and a negative electrode terminal 184, as shown in FIG. .

First, the protective glass 181 is a component for blocking the opening of the white light diffusing unit 160, and may have various shapes, for example, a circular protective glass. As shown in FIG. 3, the metal strip 182 is formed along the inner surface of the inner surface of the protective glass 181, and both ends of the metal strip 182 are spaced apart from each other.

3, the positive electrode terminal 183 is coupled to one end of the metal strip 182 and is connected to the positive electrode of the power line supplied to the laser diode 110. [ The cathode terminal 184 is coupled to the other end of the metal band 182 and is connected to a cathode of a power line supplied to the laser diode 110.

Since a highly precise optical system is mounted inside the white light emitting device 100 according to the present embodiment, a protective glass 181 is installed in order to prevent an accident that a contaminant is invaded from the outside to lose performance. In addition, a circuit is formed on the surface of the protective glass so that the protective glass 181 may be damaged, and power is supplied to the laser diode via the circuit, so that when the airtightness is lowered or the glass is broken, So as to be automatically interrupted.

100: An industrial lighting device using a blue laser diode and a phosphor according to an embodiment of the present invention
110: blue laser generator 120:
130: power socket 140: light focusing part
150: phosphor section 160: white light diffusing section

Claims (6)

A blue laser generator in which a plurality of blue laser diodes for radiating a blue laser beam forward are radially arranged;
An installation body for providing a space for installing the plurality of blue laser diodes so that a plurality of laser beams irradiated from the plurality of blue laser diodes are collected at a specified forward position;
A power socket having a structure coupled to a rear portion of the installation body and coupled to a bulb installation device capable of coupling an incandescent bulb, and connected to the bulb installation device to supply power to the blue laser generation portion;
A light focusing unit installed in front of the blue laser diode and focusing the laser beams emitted from the blue laser diode into parallel light and condensing the laser beams at a specific point;
A phosphor unit installed at a specific point forward of the light focusing unit and converting the blue laser condensed by the light focusing unit into white light;
A white light diffusing unit disposed at the rear of the phosphor unit to irradiate the white light converted by the phosphor unit in the front direction of the phosphor unit;
A phosphor driving unit coupled to a rear end of the phosphor unit to drive the phosphor unit forward and backward;
And a phosphor mounting part coupled to the phosphor driving part and fixing the phosphor part and the phosphor driving part to the white light diffusing part,
The phosphor-
A circular protective glass for blocking the opening of the white light diffusing portion;
A metal band formed along an inner peripheral surface of the protective glass;
A cathode terminal connected to one end of the metal strip and connected to an anode of a power supply line supplied to the laser diode;
And an anode terminal coupled to the other end of the metal strip and connected to a cathode of a power line supplied to the laser diode. The optical scanning device according to claim 1,
And an aspheric lens. The industrial lighting apparatus using the blue laser diode and the phosphor. 2. The phosphor according to claim 1,
Wherein the phosphor is a crystal type phosphor. delete delete The method according to claim 1,
An outer cover which is fastened in a state where the protective glass is interposed in an installation groove of the white light diffusion portion;
And an airtight gasket provided between the outer cover and the white light diffusing unit to seal the space inside the white light diffusing unit.

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