KR20160005568A - Plasma lighting system - Google Patents

Abstract

According to an embodiment, an electrodeless lighting system comprises: a magnetron for receiving a high voltage and generating microwaves; a waveguide which is coupled to the magnetron and guides the microwaves set off from the magnetron; a resonant reflector which is coupled to an outlet side, blocks the external emission of the microwaves to form a resonant mode, and guides light in one direction; and an electrodeless bulb which is arranged inside the resonant reflector and has light-emitting materials to emit light by being excited by the microwaves. The resonant reflector includes: a reflection unit which contains a conductive material and reflects light generated from the electrodeless bulb; a flood cover which covers the front side of the reflection unit, is made of a conductive material, and has a plurality of light-transmitting holes; and an electromagnetic wave shield unit which blocks at least a portion of the light-transmitting holes. The electromagnetic wave shield unit transmits light and suppresses the transmission of electromagnetic waves.

Description

ELECTROLESS LIGHTING APPARATUS {PLASMA LIGHTING SYSTEM}

An embodiment relates to an electrodeless lighting device.

2. Description of the Related Art Generally, in an electrodeless lighting apparatus, microwave energy generated in a microwave generating unit that generates a microwave such as a magnetron is transmitted to a resonance reflector through a waveguide, excites a filling material of an electrodeless bulb provided in the resonator, The charged gas of the electrodeless bulb is converted into a plasma state to generate light.

The electrodeless lighting device has an electrode or filament-free electrodeless bulb inside the bulb which has a very long lifetime or is semi-permanent. Also, the filling material filled in the electrodeless bulb is made to be plasmatized to emit light like natural light Thereby emitting light.

The resonator transmits light generated from the electrodeless bulb and suppresses the emission of electromagnetic waves.

However, such a resonator is generally formed of a conductive material in the form of a mesh. In order to sufficiently shield the electromagnetic wave from the outside, the thickness of the mesh must be increased or the opening space of the mesh must be reduced.

However, if the thickness of the mesh is increased and the opening space of the mesh is reduced, the light generated from the electrodeless bulb can not be transmitted to the outside, thereby significantly reducing the light efficiency of the lighting apparatus.

In addition, a general electrodeless lighting device uses a reflector that surrounds a resonator to guide light generated from an electrodeless bulb in one direction.

An object of the present invention is to provide an electrodeless lighting device which cuts off electromagnetic waves flowing out to the outside, has excellent optical efficiency, and reduces manufacturing cost.

An electrodeless lighting device according to an embodiment of the present invention includes a magnetron for generating a microwave by applying a high voltage thereto, a waveguide coupled to the magnetron for guiding the microwave emitted from the magnetron, an outer waveguide coupled to the outlet of the waveguide, An electrodeless reflector for forming a resonance mode and guiding light in one direction and an electrodeless bulb disposed inside the resonance reflector and excited by microwaves and provided with a light emitting material to emit light, A light projecting cover covering a front portion of the reflection portion and made of a conductive material and having a plurality of light transmission holes, at least a part of the light transmission holes, And an electromagnetic wave shielding unit for shielding the electromagnetic wave, Is light and transmitting, characterized by suppressing the transmission of electromagnetic waves.

Therefore, the embodiment has an advantage that the amount of the light emitted to the outside is maintained while the amount of the electromagnetic wave radiated to the outside through the resonance reflector is remarkably reduced.

Further, the embodiment has an advantage that the electromagnetic wave shielding ratio and the light efficiency can be easily controlled through the arrangement of the electromagnetic wave shielding portion.

In addition, in the embodiment, there is an advantage that manufacturing is easy and manufacturing cost is reduced by using a resonant reflector having the function of a resonator and a reflector.

1 is a perspective view of an electrodeless lighting device according to an embodiment of the present invention,
FIG. 2 is a side view of the electrodeless lighting device of FIG. 1,
FIG. 3 is a side sectional view of the electrodeless lighting device of FIG. 1,
4 is a cross-sectional view of a resonant reflector according to an embodiment of the present invention.
5 is a plan view of a light-transmitting cover according to an embodiment of the present invention.
6 is a cross-sectional view of a resonant reflector according to another embodiment of the present invention.
7 is a partial cross-sectional view of a resonance reflector according to another embodiment of the present invention.
8 is a partial cross-sectional view of a resonance reflector according to another embodiment of the present invention.

The angles and directions referred to in the process of describing 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.

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

FIG. 1 is a perspective view of an electrodeless lighting device according to an embodiment of the present invention, and FIG. 2 is a side view of the electrodeless lighting device of FIG.

Referring to FIGS. 1 and 2, the electrodeless lighting apparatus 10 is formed with a main body having an outer appearance by a casing 100 having a predetermined space therein.

In addition, a plurality of electric components can be embedded in the casing 100.

The casing 100 may have a roughly hexahedral shape.

On the outer surface of the casing (100), a support portion (550) for fixing the body to the outer space is provided.

Both ends of the supporter 550 are rotatably fixed to the outer surface of the casing 100.

3 is a side sectional view of the electrodeless lighting device of FIG.

The electrodeless lighting device 10 of the embodiment includes a casing 100 having an inlet 127 through which outside air flows into one side and an outlet 122 through which air flowing in through the inlet 127 flows out from the other side, A magnetron 300 for generating a microwave by applying a high voltage generated from the high voltage generator 200 and a waveguide 400 for guiding a microwave oscillated from the magnetron 300, A resonance reflector 500 coupled to the outlet 430 side of the waveguide 400 to shield the external emission of microwaves to form a resonance mode and to guide the light in one direction and disposed inside the resonance reflector 500 And an electroluminescent lamp 600 excited by microwaves and provided with a light emitting material to emit light.

In addition, the electrodeless lighting device 10 of the embodiment may further include a motor M for supplying a rotational force to the electrodeless bulb 600.

Referring to FIG. 3, the casing 100 has a hexahedron shape in which an inlet 127 is formed at one side and an outlet 122 is formed at the other side, and a space in which a plurality of parts are located is formed.

Specifically, the casing 100 is formed with an inlet 127 through which air flows in the upper portion (refer to FIG. 3), and an outlet 122 through which the air introduced from the outside flows out. However, the present invention is not limited thereto, and the positions of the outlet 122 and the inlet 127 may be variously modified. Accordingly, during normal operation of the electrodeless lighting apparatus 10, an air flow is formed in the direction from the inlet 127 to the outlet 122 to cool internal components of the casing 100.

The casing 100 may be formed by engagement of at least two casing members.

Specifically, in the casing 100, the upper casing member 110 and the lower casing member 120 may be coupled to each other and a space may be formed therein.

The upper casing member 110 has an inlet 127 through which external air flows.

Specifically, an inlet 127 is formed by the rim member 113 of the upper casing member 110.

The edge member 113 may be formed with a foreign matter restricting tuck 115 which is recessed inward of the casing 100 to catch foreign substances.

Specifically, the outlet 122 may be disposed below the lower casing member 120.

The outlet 122 may be spaced apart from the inlet 127 such that the air introduced into the casing 100 can receive and discharge heat from components within the casing 100.

More specifically, the outlet 122 may be formed at the lower left of the lower casing member 120.

An inlet cover 830 may be positioned above the inlet 127 to bypass the air entering the inlet 127.

The inlet cover 830 shields the upper area of the inlet 127 (as shown in FIG. 3) so that the outside air can not be directly sucked into the inlet 127.

Specifically, the outside air flows from the outside of the casing 100 toward the inlet 127, flows outwardly between the rims of the inlet cover 830 and the inlet 127 in the middle, Is sucked into the casing (100) by the suction force of the suction pipe (151).

For example, the inlet cover 830 may be spaced apart by a spacer (not shown) and a rim member 113 forming the inlet 127.

Further, the embodiment may further include an insect cover 810 covering the inlet cover 830. [

The insect-proof cover 810 is disposed so as to surround the inlet cover 830.

Specifically, the insect-proof cover 810 has a larger cross-sectional area of the inlet cover 830 and can be arranged to at least cover the upper area of the inlet cover 830.

The insectproof cover 810 may include a cover body 811 forming a main body and a ventilation hole 813 formed in a part of the cover main body 811 for dustproof and insect proofing.

The ventilation hole 813 may be in the form of a hole having a predetermined size in order to prevent inflow of external air, such as insects, dust, etc., into the ventilation hole 813.

The casing 100 may further include an air flow unit 151 for allowing external air to flow from the inlet 127 toward the outlet 122.

The air flow unit 151 is a device that generates a pressure difference of air to flow air in one direction. For example, the air flow unit 150 may be an axial flow fan.

The air flow unit 150 is located inside the casing 100 and allows the outside air to flow in the direction of the inlet 127 toward the outlet 122. [

The high voltage generator 200 generates a high voltage and supplies it to the magnetron 300.

For example, the high voltage generator 200 may include a boosting unit for boosting the drive circuit and the power source.

The magnetron 300 is located inside the casing 100 and can generate microwaves by applying a high voltage generated from the high voltage generator 200.

When a drive signal is input to the high voltage generator 200, the high voltage generator 200 boosts the AC power to supply the boosted high voltage to the magnetron 300. The magnetron 300 oscillates at a high voltage, Thereby generating microwaves having the same wavelength.

The microwave is emitted to the outside of the magnetron 300 through the antenna 310 of the magnetron 300. The emitted microwave is impedance-matched by a microwave matching member (not shown) of the magnetron 300, 400.

The waveguide 400 is coupled to the magnetron 300 to guide the microwave emitted from the magnetron 300 into the resonant reflector 500.

The waveguide 400 may be formed to have a waveguide space S in which microwaves are guided.

The waveguide 400 may also be disposed between the inlet 127 and the outlet 122 and may be cooled by the outside air introduced at the inlet 127.

An outlet 430 may be formed in a lower portion of the waveguide 400 in one direction. Holes (not shown) corresponding to the outlets of the waveguide 400 may be formed in the lower casing member 120.

The outlet 430 of the waveguide 400 allows the waveguide space S in the waveguide 400 to communicate with the resonant space 530 in the resonant reflector 500.

Specifically, the outlet 430 of the waveguide 400 is formed through the lower surface of the waveguide 400.

Preferably, the outlet 430 of the waveguide 400 may be positioned adjacent to the electrodeless bulb 600.

That is, the outlet 430 of the waveguide 400 is preferably positioned adjacent to the electrodeless bulb 600, which is a position where the electric field can be maximized

The shape of the exit 430 of the waveguide 400 is not limited, but may preferably have a shape corresponding to the shape of the horizontal cross section of the resonant reflector 500.

The electrodeless bulb 600 is disposed inside the resonant reflector 500 and excited by microwaves to emit light.

At this time, the light emitting material filled in the inner space of the electrodeless bulb 600 allows the user to emit visible light of a desired wavelength. That is, when the user wants to change the visible light emitted from the electrodeless bulb 600 by changing the luminescent material when the user wishes to emit visible light of a long wavelength and the luminescent material when the user wants to emit visible light with a short wavelength, .

The electrodeless bulb 600 and the resonant reflector 500 may be disposed in a lower region of the exterior of the casing 100.

A motor (M) for rotating the electrodeless bulb (600) may be positioned inside the casing (100).

The motor M supplies rotational force to the electrodeless bulb 600.

The motor M rotates the electrodeless bulb 600 to cool the electrodeless bulb 600.

The motor M is connected to the electrodeless bulb 600 by a rotation axis 620.

The resonance reflector 500 is coupled to the outlet 430 side of the wave guide 400 to shield the external emission of the microwave to form a resonance mode.

The microwaves flowing in the waveguide 400 flow into the inner space of the resonant reflector 500 to form a resonance mode.

The resonant reflector 500 is coupled to the outer surface of the waveguide 400 so as to surround at least the outlet 430 of the waveguide 400.

In addition, a resonance space 530 may be formed in the resonance reflector 500. The electrodeless bulb 600 may be positioned in the resonant space 530.

Hereinafter, the resonance reflector 500 will be described in detail.

FIG. 4 is a cross-sectional view of a resonant reflector according to an embodiment of the present invention, and FIG. 5 is a plan view of a transparent cover according to an embodiment of the present invention.

4 and 5, the resonant reflector 500 has a resonant space 530 capable of accommodating the electrodeless bulb 600 therein, and has a resonant space 530 in which a microwave is supplied from the outlet 430 of the wave guide 400 As shown in Fig.

Also, the resonant reflector 500 can guide the light generated in the electrodeless bulb 600 in one direction.

For example, the resonance reflector 500 may include a reflecting portion 520, a light-transmitting cover 510, and an electromagnetic wave shielding portion 530.

The reflector 520 reflects the light generated from the electrodeless bulb 600 in one direction and shields the microwave supplied from the outlet 430 of the wave guide 400.

The reflective portion 520 may include a conductive material having a high reflectivity. For example, the reflective portion 520 may be formed entirely of a conductive material. As another example, the body of the reflection portion 520 may be formed of a resin material, and the inner surface thereof may be coated with a conductive material.

Specifically, the inner surface of the reflective portion 520 may be coated with any one of Ag, Ag alloy, Al, and Al alloy.

The reflective portion 520 may have a shape in which a space in which the electrodeless bulb 600 is located and a front portion (downward in FIG. 4) is opened. A front opening 521 is formed at the front end of the reflecting portion 520.

For example, the reflecting portion 520 may have a columnar shape with a diameter increasing as it goes forward. A rear opening 523 may be formed at the rear end of the reflector 520 so that the microwave is supplied from the outlet 430 of the wave guide 400.

Here, the rear opening 523 may correspond to the size of the outlet 430 of the waveguide 400, and may be a size that wraps the electrode 430 of the electrodeless fluorescent lamp 600 and the outlet 430 of the waveguide 400, . 4, the rear opening 523 has a size to enclose the electrodeless bulb 600 and the outlet 430 of the waveguide 400.

At this time, the rear opening 523 of the reflection part 520 may be shielded by one surface of the waveguide 400 or one surface of the casing 100. A conductive material may be coated on one surface of the waveguide 400 that shields the rear opening 523 of the reflector 520 or on one surface of the casing 100.

The front end of the reflector 520 may be bent outwardly to form a flange 590 having a certain area along the rim of the front end of the reflector 520. The flange 590 is coupled to the light-transmitting cover 510.

The reflecting portion 520 may be fixed to the lower casing member 120 by a fixing member 740.

The light-transmitting cover 510 allows the microwaves generated in the resonance space 530 to pass through, while allowing the light to emit.

The transparent cover 510 forms a resonance space 530 together with the reflector 520 so that the resonance mode in the resonance space 530 can form the TE mode. At this time, the light generated from the electrodeless bulb 600 is reflected by the reflection unit 520 and transmitted through the transparent cover 510.

The light-transmissive cover 510 covers the front of the reflective portion 520. For example, the light-transmitting cover 510 may cover the front opening 521 of the reflecting portion 520. [ Specifically, the rim of the light-transmitting cover 510 can be coupled to the flange 590 of the reflection portion 520.

The light-transmitting cover 510 may be made of a conductive material, for example, a metal material, in order to shield microwaves or electromagnetic waves.

Specifically, the light transmitting cover 510 has a plurality of light transmitting holes 511 formed therein.

The light transmission hole 511 is a region through which the light in the resonance space 530 is transmitted to the outside.

For example, the light transmitting hole 511 may be an opening formed through the light transmitting cover 510.

As another example, the light transmitting hole 511 may be defined as an empty space when the light transmitting cover 510 is formed in a mesh (net) shape.

The light transmitting apertures 511 may be arranged regularly or irregularly.

The shape of the light transmission hole 511 may be circular or polygonal. The electromagnetic wave and the light are blocked by the transparent cover 510, and the electromagnetic wave and the light are transmitted through the light transmitting hole 511 formed in the transparent cover 510.

Preferably, the shape of the light transmitting hole 511 may have a hexagonal shape that minimizes the area of the light transmitting cover 510 and maximizes the area of the light transmitting hole 511.

When the width d2 of the light transmitting hole 511 is too large, the amount of light transmitted through the light transmitting hole 511 is increased, but the amount of electromagnetic waves transmitted through the light transmitting hole 511 is also increased. When the width d2 of the light transmitting hole 511 is too small, the amount of electromagnetic waves transmitted through the light transmitting hole 511 is reduced, but the amount of light transmitted through the light transmitting hole 511 is also reduced.

Here, the width of the light transmitting hole 511 means the diameter when the light transmitting hole 511 is circular, and the average width when the light transmitting hole 511 is polygonal.

Also, if the thickness d1 of the transparent cover 510 is large, the amount of electromagnetic waves transmitted through the light transmitting hole 511 is reduced, but the amount of light transmitted through the light transmitting hole 511 is also reduced. If the thickness d1 of the transparent cover 510 is small, the amount of light transmitted through the light transmitting hole 511 is increased, but the amount of electromagnetic waves transmitted through the light transmitting hole 511 is also increased.

As a result, the electrodeless lighting apparatus 10 adjusts the thickness d1 of the transparent cover 510 and the width d2 of the light transmitting hole 511 to match the electromagnetic interference (EMI) standard. However, when the electrodeless lighting device 10 complies with the electromagnetic wave standard, there is a problem that the amount of light transmitted through the light transmitting hole 511 and emitted to the outside becomes small.

Therefore, the resonance reflector 500 of the embodiment uses the electromagnetic wave shielding part 530 to solve the above-described problem. [0154] In the embodiment, the resonance reflector 500 is not provided with the resonator The function of the reflector is performed in parallel.

The electromagnetic wave shielding unit (530) transmits light and suppresses (attenuates) the transmission of electromagnetic waves.

The electromagnetic wave shielding part 530 shields at least part of the light transmitting holes 511 of the electromagnetic wave shielding part 530. Specifically, the electromagnetic wave shielding part 530 may be enclosed in some or all of the light transmitting holes 511 .

The electromagnetic wave shielding unit 530 may be located on some or all of the light transmitting holes 511 in consideration of the electromagnetic wave shielding rate of the electrodeless lighting apparatus 10. [

The thickness of the electromagnetic wave shielding part 530 may be set in consideration of the light efficiency without any limitation. Preferably, the thickness of the electromagnetic wave shielding part 530 may correspond to the thickness of the light transmitting cover 510 .

For example, the electromagnetic wave shielding unit 530 may be formed of a dielectric material, which is a material that generates electric polarization when an electrostatic field is applied, but does not cause a direct current. Both nonpolar and polar molecules form electric dipole moments that cancel the electric field around them.

When a dielectric is used in the electromagnetic wave shielding part (530), electromagnetic waves generated in the resonance space (530) can be attenuated.

Specifically, the electromagnetic shield section (530 may be a light comprising a high permeability dielectric material, for example, the dielectric is SiO ₂ (silicon oxide), TiO ₂ (titanium oxide), Y ₂ O _3, ZrO ₂ , MgO, Al ₂ O _3, and Ta ₂ O ₅ .

The light generated by the electrodeless bulb 600 is reflected by the transparent cover 510 but is transmitted through the electromagnetic wave shielding unit 530 formed of a dielectric material so that the electromagnetic waves of the electrodeless lighting apparatus 10 are reduced, So that the light efficiency can be maintained.

In particular, when the same electromagnetic wave standard is to be complied with, the thickness d1 of the light-transmitting cover 510 and the width d2 of the light transmitting hole 511 of the embodiment are reduced as compared with the conventional case.

The light generated by the electrodeless bulb 600 is refracted by the electromagnetic wave shielding unit 530 when the electromagnetic wave shielding unit 530 transmits the electromagnetic wave shielding unit 530. Particularly, Part of the light traveling to the outside is totally reflected.

Total reflection is a phenomenon in which the light is totally reflected (100% reflection) at the interface when the incident angle is larger than the critical angle when the light travels from the medium having a large refractive index to the medium having a small refractive index.

Therefore, the electromagnetic wave shielding unit 530 may have a refractive index similar to the refractive index of the outside of the resonance reflector 500 (specifically, the refractive index of air 1). Preferably, the electromagnetic wave shielding unit 530 has a refractive index of 1.4 a it may be formed of silicon oxide (SiO _2).

The concave and convex portions may be formed on the outer surface of the electromagnetic wave shielding portion 530 (the surface of the electromagnetic wave shielding portion 530 adjacent to the outside of the resonant reflector 500).

The irregularities may be irregularly formed on the irregular surface, and the irregularities are not limited thereto.

The concavities and convexities may be formed to have various shapes such as a cylinder, a polygonal column, a cone, a polygonal pyramid, a truncated cone, a polygonal pyramid, and the like.

As the unevenness is formed on the outer surface of the electromagnetic wave shielding part 530, light generated in the electrodeless bulb 600 can be prevented from being totally reflected by the outer surface of the electromagnetic wave shielding part 530 and reabsorbed or scattered, Thereby contributing to improvement in light extraction efficiency.

The irregularities may be formed by a dry etching method or a wet etching method.

The electromagnetic wave shielding unit 530 may be located at least a part of the light transmitting holes 511. That is, the electromagnetic wave shielding unit 530 may block some or all of the plurality of light transmitting holes 511 . For example, as shown in Fig. 4, the electromagnetic wave shielding part (530) may be located in a part of the light transmitting holes 511. [

 6 is a cross-sectional view of a resonant reflector according to another embodiment of the present invention.

6, the resonator reflector 500A according to the embodiment is different from the embodiment of FIG. 4 in that the arrangement of the electromagnetic wave shielding portion 530, the shape of the reflection portion 520A, and the front glass 540 Have a difference.

The electromagnetic wave shielding part (530) covers the entire surface of the transparent cover 510. [

For example, the electromagnetic wave shielding portion (530) may be arranged to cover the entire light transmitting hole (511).

As another example, the light-transmitting cover 510 may be embedded in the electromagnetic wave blocking portion 530. [

The thickness of the electromagnetic wave shielding part 530 may be different from the thickness of the transparent cover 510 or may be the same.

The reflective portion 520 may have a closed shape at the rear end. The outlet 430 of the waveguide 400 and the holes 525 and 527 corresponding to the rotation axis 620 of the motor M may be formed at the rear end of the reflection unit 520.

Since most of the rear end of the reflection part 520 has a closed shape, coating is not required on the outer surface of the casing 100 or on one surface of the wave guide 400.

The front glass 540 covers the front of the reflector 520 and protects the inside of the reflector 520 and transmits light generated from the electrodeless bulb 600.

For example, the front glass 540 can cover the front opening 521 of the reflecting portion 520. [ Specifically, the rim of the windshield 540 may be coupled to the flange 590 of the reflector 520. [

Specifically, the front glass 540 may have a shape and a size corresponding to the transparent cover 510.

More specifically, the windshield 540 may be bonded to the front surface or rear surface of the light-transmitting cover 510.

The front glass 540 has a constant strength, so that the bonded light transmitting cover 510 can be protected.

At this time, SiO ₂ (silicon oxide) having a refractive index similar to that of glass is used as the dielectric of the electromagnetic wave shielding part 530 to reduce the total reflection occurring at the interface between the electromagnetic wave shielding part 530 and the windshield 540 .

7 is a partial cross-sectional view of a resonance reflector according to another embodiment of the present invention.

Referring to FIG. 7, the resonance reflector 500B according to the embodiment differs from the embodiment of FIG. 6 in the arrangement of the windshield 540. FIG.

The front glass 540 of the embodiment can be positioned in front of and behind the light-transmitting cover 510. [ That is, the light-transmitting cover 510 can be buried by the windshield 540.

When the front glass 540 is positioned behind the light transmitting cover 510, the light transmitting cover 510 is easily attached to the flange 590 and the front glass 540 is positioned in front of the light transmitting cover 510 It becomes possible to protect the light transmitting cover 510 from an external impact.

Referring to FIG. 8, the resonance reflector 500C according to the embodiment differs from the embodiment of FIG. 5 in the shape of the electromagnetic wave shielding part 530 and the light-transmitting cover 510. FIG.

And may be formed in a zigzag shape in the longitudinal direction of the light transmission cover 510. [ That is, the transparent cover 510 has a slope repeated in a zigzag with respect to a line perpendicular to the optical axis.

If the light-transmitting cover 510 has such an inclination, the probability that the light incident on the light-transmitting cover 510 from the electrodeless bulb 600 is totally reflected is reduced.

A part of the electromagnetic wave shielding part 530 has a line perpendicular to the optical axis Ax or the optical axis and a first inclination and the other part of the electromagnetic wave shielding part 530 has a line perpendicular to the optical axis or optical axis, And the first inclination and the second inclination can be inclined in opposite directions.

Here, the inclination of the electromagnetic wave shielding part (530) may mean the inclination of the outer surface and / or inner surface of the electromagnetic wave shielding part (530).

That is, on the vertical plane, the electromagnetic wave shielding part 530 may be formed in a zigzag shape.

If the electromagnetic wave shielding unit 530 has such a slope, the probability that light traveling to the outside of the resonance reflector 500 in the electromagnetic wave shielding unit 530 is totally reflected is reduced.

The above-described electrodeless lighting apparatus 10 is operated as follows.

When a drive signal is input to the high voltage generator 200, the high voltage generator 200 boosts the AC power to supply the boosted high voltage to the magnetron 300. The magnetron 300 oscillates at a high voltage, Thereby generating microwaves having the same wavelength.

This microwave is emitted to the outside of the magnetron 300 through the antenna of the magnetron 300. The emitted microwave is impedance matched by a microwave matching member (not shown) of the magnetron 300, Guidance.

The microwave guided to the waveguide 400 is guided into the resonance reflector 500 through the waveguide space S of the waveguide 400 and is radiated. The resonance mode is formed inside the resonance reflector 500 by the emitted microwave .

The luminescent material charged in the electrodeless bulb 600 is excited by a resonance mode formed inside the resonant reflector 500 to be continuously plasmaized to emit light having a unique emission spectrum, And is reflected downward by the reflecting portion 520 of the light source 500 to brighten the space.

At this time, the light generated by the electrodeless bulb 600 is transmitted through the electromagnetic wave shielding unit 530, and the microwave is blocked.

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 embodiments, but, on the contrary, It will be understood that various modifications and applications are possible. For example, each component specifically shown in the embodiments can be modified and implemented. It is to be understood that all changes and modifications that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

10: Electrodeless lighting equipment
100: casing
200: High voltage generator
300: Magnetron
500: Resonant reflector

Claims (10)

A magnetron generating a microwave by applying a high voltage;
A waveguide coupled to the magnetron and guiding microwaves emitted from the magnetron;
A resonance reflector coupled to an outlet side of the waveguide to shield external emission of microwaves to form a resonance mode and to guide the light in one direction; And
And an electroluminescent bulb disposed inside the resonant reflector and being excited by microwaves and provided with a light emitting material to emit light,
The resonator reflector includes:
A reflective part including a conductive material and reflecting light generated from the electrodeless bulb;
A light-transmitting cover which covers the front of the reflecting portion and is made of a conductive material and has a plurality of light transmitting holes; And
And an electromagnetic wave shielding portion for shielding at least a part of the light transmission holes,
Wherein the electromagnetic wave shielding portion transmits light and suppresses transmission of electromagnetic waves. The method according to claim 1,
Wherein the electromagnetic wave shielding portion includes a dielectric. 3. The method of claim 2,
The dielectric material
_{SiO 2, TiO 2, Y 2} O 3, ZrO 2, MgO, Al 2 O 3 and Ta ₂ O ₅ . 3. The method of claim 2,
Wherein the electromagnetic wave shielding portion covers the entire surface of the light-transmitting cover. 5. The method of claim 4,
And the light-transmitting cover is buried in the electromagnetic wave shielding portion. The method according to any one of claims 1, 4, and 5,
The resonator reflector includes:
And a front glass covering the front of the reflection part. The method according to claim 6,
Wherein the light-transmitting cover or the electromagnetic wave shielding portion is buried in the front glass. The method according to claim 1,
The reflector includes:
Wherein a space in which the electrodeless bulb is located is formed in the interior of the bulb, and the diameter of the bulb is increased as the bulb advances forward. 9. The method of claim 8,
Wherein the inner surface of the reflective portion is coated with one of Ag, Ag alloy, Al and Al alloy. The method according to claim 1,
Wherein the light-transmitting cover is formed in a mesh shape.

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