KR20170127196A - A device for lighting white light - Google Patents

Abstract

The present invention relates to a blue laser diode which emits a blue laser beam emitted from a blue laser diode to a phosphor to obtain a scattered light of white light obtained by condensing the scattered light, thereby achieving a simple and economical method, A white light emitting device using a blue laser diode and an optical fiber according to the present invention comprises: a laser diode unit installed to irradiate a laser beam to a plurality of blue laser diodes; An installation body providing an installation space in which the plurality of blue laser diodes are installed; An optical fiber unit coupled to a front end of the plurality of blue laser diodes to guide each laser beam to a specific point in front of the installation body; A phosphor unit installed at a predetermined position in front of the installation body and converting the laser beam into white light; And a parallel light converting unit installed as a parabolic reflector on the front surface of the main body to convert the white light converted by the phosphor unit into parallel light to be irradiated forward.

Description

TECHNICAL FIELD [0001] The present invention relates to a white light emitting device using a blue laser diode and an optical fiber,

The present invention relates to a white light emitting device, and more particularly, to a white light emitting device that emits a blue laser beam emitted from a blue laser diode to a phosphor by using an optical fiber, collects white light in scattered light form, And to a white light emitting device using a blue laser diode and an optical fiber that can realize white light in an economical manner.

First, blue light and phosphors are used as a method for realizing white light. When a blue beam is irradiated on a phosphor surface, a blue beam is reflected on the phosphor surface to generate white scattered light. Second, blue, green and red beams This is a method of obtaining white light by irradiating one place.

Such a white light emitting method is a disadvantage in that it is very complicated or difficult to implement a device that meets lighting conditions. It is common sense that a conventional illumination light source is a light source in which white light is the most common and enhances the visibility of an object. However, there are many light sources that emit white light, but when a desired illumination area is irradiated, only a part of the total divergent light is irradiated to the corresponding area, so that the light loss becomes very large, and more light loss is required at a long distance.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a simple and economical method of extracting a scattering light-type white light obtained by irradiating a blue laser beam emitted from a blue laser diode to a phosphor using an optical fiber, A blue laser diode capable of realizing white light and a white light irradiation device using an optical fiber.

According to an aspect of the present invention, there is provided a white light emitting apparatus using a blue laser diode and an optical fiber, the apparatus including: a laser diode unit installed to irradiate a laser beam to each of a plurality of blue laser diodes; An installation body providing an installation space in which the plurality of blue laser diodes are installed; An optical fiber unit coupled to a front end of the plurality of blue laser diodes to guide each laser beam to a specific point in front of the installation body; A phosphor unit installed at a predetermined position in front of the installation body and converting the laser beam into white light; And a parallel light converting unit installed as a parabolic reflector on the front surface of the main body to convert the white light converted by the phosphor unit into parallel light to be irradiated forward.

In the white light emitting device using the blue laser diode and the optical fiber according to the present invention, a laser beam is provided between the laser diode and the optical fiber, and the laser diode and the optical fiber are coupled to each other. It is preferable to further include an adapter for transmitting the data.

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

The white light emitting device using the blue laser diode and the optical fiber 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 unit coupled to the phosphor driving unit and for coupling the phosphor unit and the phosphor driving unit to the white light converting unit.

Further, in the present invention, the phosphor mounting part may include: a circular protective glass for blocking an opening of the white light converting part; 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 white light emitting device using the laser diode and the optical fiber according to the present invention may further include: an outer cover which is fastened with the protective glass interposed in the installation groove of the white light conversion part; And a sealing gasket provided between the outer cover and the white light conversion unit to seal the space inside the white light conversion unit.

The present invention is capable of realizing white light in a simple and economical way by avoiding complex and difficult overlapping that is used in the implementation of conventional white light and securing diversity of optical path configuration utilizing optical fiber characteristics, There is an advantage that new concepts can be introduced in devices and the like.

Fig. 1 is a diagram showing a configuration of a white light emitting device according to an embodiment of the present invention.
2 is a view showing an optical path of a white light emitting device according to an embodiment of the present invention.
3 is a view showing a structure of a protective glass part 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, a white light emitting device 100 using a blue laser diode and an optical fiber according to the present embodiment includes a laser diode unit 110, an installation body 120, an optical fiber unit 130, a phosphor unit (not shown) 140 and a parallel light conversion unit 150. [

1, a plurality of blue laser diodes 111, 112, and 113 are provided to irradiate laser beams, respectively, and each laser diode is configured to emit a generally known laser diode as it is Can be used. In this embodiment, the laser beams irradiated from the respective laser diodes 111, 112 and 113 are guided by the optical fiber unit 130, so that the arrangement state thereof can be variously changed. Further, a plurality of laser diode portions irradiate blue laser beams, respectively.

Next, the mounting body 120 is a component for providing an installation space in which the plurality of blue laser diodes 110 are installed, and may not be installed if necessary.

1, the optical fiber unit 130 is coupled to the front ends of the plurality of blue laser diodes 110 to guide the laser beams to specific points in front of the installation body 120 Element. The optical fiber unit 130 may include optical fibers coupled to the plurality of blue laser diodes 110 to guide the blue laser beam toward the phosphor unit 140 without loss of light.

At this time, it is preferable that the white light emitting device 100 according to the present embodiment further includes an adapter 160, as shown in FIG. The adapter 160 is installed between the laser diode 110 and the optical fiber 130 and couples the laser diode and the optical fiber so that the laser beam output from the laser diode 110 is transmitted to the optical fiber 130 without flowing out. As shown in FIG.

Since the diameter of the optical fiber 130 is very constant, the diameter of the laser beam output through the optical fiber can be uniformly adjusted. Therefore, when the optical fiber is connected using the adapter 160 near the beam output end of the laser diode 110, the laser beam is incident into the optical fiber 130 and propagates to the end while causing total internal reflection.

1, the phosphor unit 140 is installed at a specific point in front of the installation body 120, and is a component for converting the laser beam into white light. Since the laser beam used in the present embodiment is focused and irradiated to the phosphor, the organic phosphor which does not guarantee the heat resistance 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, the phosphor driving unit 170 and the phosphor mounting unit 180 may be further included in the white light emitting device 100 according to the present embodiment. If the focal point of the parallel light converter 150 (to be described later) and the phosphor are not in the same position, even when the white light is diverged in the phosphor 140, the divergence angle is increased when parallel light is converted and used. Therefore, it is necessary to have a mechanical structure capable of changing the focal length or varying the position of the phosphor 140.

1, the phosphor driving unit 170 is coupled to a rear end of the phosphor unit 140 and has a structure for driving the phosphor unit 140 forward and backward. For example, the phosphor driving unit 170 is coupled to a rear end of the phosphor unit 140, and rotates the phosphor unit 140 along the screw structure with respect to the phosphor mounting unit 180 to drive the phosphor unit 140 back and forth Lt; / RTI >

1, the phosphor mounting unit 180 is coupled to the phosphor driving unit 170, and the phosphor unit 140 and the phosphor driving unit 170 are connected to the white light converting unit 150, Or to the installation body 120. As shown in Fig. Therefore, it is preferable that the phosphor mounting part 180 has a spiral structure that can be fastened to the front end of the mounting body 120 or the white light converting part, and is made of a material that can transmit white light.

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. .

The protective glass 181 is a component for blocking the opening of the installation body 120 and may have various shapes and may be formed of, 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 as to detect whether the protective glass 181 is broken, and power is supplied to the laser diode 100 via the circuit, so that when the airtightness is lowered or glass breakage occurs, So that the laser power is automatically cut off.

1, the parallel light converter 150 is installed as a parabolic reflector with the front face of the installation body 120 being engraved, and the white light converted by the phosphor unit 140 is directed forward Into a parallel light to be irradiated. The parallel light conversion unit 150 is a component having the parabolic reflector whose focal length corresponds to the phosphor unit 140. That is, as shown in FIG. 2, the parallel light converter 150 reflects white light emitted in the form of diffused light through the phosphor unit 140 disposed at the focal position, and converts the white light into parallel light.

100: a white light irradiation device using a blue laser diode and an optical fiber according to an embodiment of the present invention
110: laser diode part 120: installation body
130: optical fiber part 140: phosphor part
150: parallel light conversion section

Claims (6)

A plurality of blue laser diodes arranged to irradiate a laser beam;
An installation body providing an installation space in which the plurality of blue laser diodes are installed;
An optical fiber unit coupled to a front end of the plurality of blue laser diodes to guide each laser beam to a specific point in front of the installation body;
A phosphor unit installed at a predetermined position in front of the installation body and converting the laser beam into white light;
And a collimated light converting unit that is installed as a parabolic reflector on the front surface of the main body and converts the white light converted by the phosphor unit into parallel light to be forwardly illuminated, . The method according to claim 1,
And an adapter installed between the laser diode and the optical fiber and coupling the laser diode and the optical fiber to transmit the laser beam output from the laser diode to the optical fiber without leakage. The white light irradiation device. 2. The phosphor according to claim 1,
Wherein the phosphor is a crystal type phosphor. The method of claim 3,
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 coupling the phosphor part and the phosphor driving part to the white light converting part. 5. The phosphor according to claim 4,
A circular protective glass for blocking the opening of the white light converting part;
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 supply line supplied to the laser diode. 6. The method of claim 5,
An outer cover which is fastened in a state where the protective glass is interposed in an installation groove of the white light conversion portion;
And a sealing gasket provided between the outer cover and the white light converting unit to seal the space inside the white light converting unit.

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