KR100548277B1 - Lamp cover structure of electrodeless lighting system - Google Patents

Abstract

The lamp cover structure of the electrodeless lighting device of the present invention includes a magnetron for converting electrical energy into high frequency energy rolls; A resonator in which an output portion of the magnetron is inserted at an inlet side and a resonant space in which electromagnetic waves resonate is formed inside; An electromagnetic feeder having one end connected to an output of the magnetron, for inducing electromagnetic waves generated from the magnetron into a resonance space; A lamp connected to the other end of the electromagnetic feeder and containing a light emitting material that emits light due to plasma discharge by electromagnetic waves; A reflector disposed around the lamp to reflect light emitted from the lamp in a specific direction; In the electrodeless lighting device, which is coupled to the exit side of the reflector to block the leakage of electromagnetic waves and protects the lamp from the outside, the lamp cover blocks the leakage of electromagnetic waves and reflects light. The cover body is made of a tubular cover body having a predetermined height so as to reduce the pressure, and the partition plate formed in a predetermined shape inside the cover body, so that electromagnetic waves resonating when the lamp emits light are leaked through the lamp cover. The light is blocked, and the light is not reflected but is mostly passed through the partition plates to be reflected, thereby improving the luminous efficiency of the lighting device.

Description

Lamp cover structure of electrodeless lighting equipment {LAMP COVER STRUCTURE OF ELECTRODELESS LIGHTING SYSTEM}

1 is a longitudinal sectional view showing a conventional electrodeless lighting device.

Figure 2 is a front view showing a lamp cover structure of a conventional electrodeless lighting device.

Figure 3 is a perspective view showing a partially broken electrodeless lighting device having a lamp cover structure according to an embodiment of the present invention.

4 is a longitudinal cross-sectional view of FIG.

5 is a front view of the lamp cover according to an embodiment of the present invention.

Figure 6 is a front view showing another embodiment of the lamp cover according to the present invention.

Figure 7 is a front view showing another embodiment of the lamp cover according to the present invention.

8 is a front view showing another embodiment of the lamp cover according to the present invention.

Explanation of symbols on the main parts of the drawings

101: magnetron 103: resonance space

104: resonator 105: electromagnetic feeder

106: lamp 107: reflector

108: lamp cover 121: cover body

122: partition plate

The present invention relates to an electrodeless illuminator, and more particularly, to improve the structure of the mirror installed to reflect the light emitted from the bulb, the mirror of the electrodeless illuminator to obtain a large light efficiency with a small size mirror It's about structure.

ELECTRODELESS LIGHTING SYSTEM is an luminaire that transmits electromagnetic energy generated from a microwave generator to a resonator, and is applied to an electrodeless lamp installed inside the resonator so that the lamp emits visible or ultraviolet rays. Compared to incandescent lamps and fluorescent lamps used for longer lifespan, the light effect is excellent.

1 is a longitudinal cross-sectional view showing a conventional electrodeless lighting device, Figure 2 is a front view showing a lamp cover structure of a conventional electrodeless lighting device, as shown, for converting electrical energy into high-frequency energy, such as electromagnetic waves Horizontally formed horizontally so as to communicate with the vertical space portion (3) and the vertical space portion (3) formed in the vertical direction so that the magnetron (1), and the antenna (2) output portion of the magnetron 1 can be inserted The resonator 6 having the resonant space 5 formed as the space part 4 and the electromagnetic wave radiated from the antenna 2 of the magnetron 1 installed inside the resonant space 5 is resonated. Electromagnetic feeder 7 for guiding to the space 5, and one end of the electromagnetic feeder 7, and the luminescent material is plasmaized by the electromagnetic wave induced through the electromagnetic wave Peter 7 to emit light The lamp 8 enclosed and its It is installed to surround the outside of the frame 8 and the reflector 9 for reflecting the light emitted from the lamp 8 in a specific direction, and coupled to the outlet side of the reflector 9 to block the leakage of electromagnetic waves; In addition, it is composed of a lamp cover 10 for protecting the lamp (8).

And, as shown in Figure 2, the lamp cover 10, the cover body 11 of a circular frame body having a predetermined diameter, and the electromagnetic shielding network is installed inside the cover body 11 and mesh-like It consists of 12 pieces.

In the conventional electrodeless lighting device configured as described above, when power is supplied to the magnetron 1 from the power supply unit, the magnetron 1 generates electromagnetic waves having high frequency energy through the antenna 2.

The electromagnetic waves generated as described above are guided to the inside of the resonant space 5 through the electromagnetic feeder 7 to resonate, and an appropriate resonant frequency is selected, and the electromagnetic waves of the selected resonant frequency resonate inside the resonant space 5. The light emitting material encapsulated in the lamp 8 is discharged to form a plasma, and the plasma emits light of high luminosity by continuously maintaining the discharge by electromagnetic waves.

The light emitted as described above is reflected to the front side by the reflector 9 to illuminate the required space, and in the lamp cover 10 provided at the exit side of the reflector 9, electromagnetic waves leak out to the outside by the electromagnetic wave shielding network 12. At the same time, light is blocked and light is emitted and emitted as it is.

However, in the conventional electrodeless lighting device configured as described above, since the lamp cover 10 is a mesh having a very small diameter, a large amount of light passing through the lamp cover 10 is reflected, causing light loss. .

An object of the present invention devised in view of the above problems is to minimize the reflection of the light passing through the lamp cover to reduce the light loss caused by the lamp cover, the electrodeless lighting suitable for increasing the light efficiency of the device It is to provide a lamp cover structure of the device.

In order to achieve the object of the present invention as described above

A magnetron for converting electrical energy into high frequency energy; A resonator in which an output portion of the magnetron is inserted at an inlet side and a resonant space in which electromagnetic waves resonate is formed inside; An electromagnetic feeder having one end connected to an output of the magnetron, for inducing electromagnetic waves generated from the magnetron into a resonance space; A lamp connected to the other end of the electromagnetic feeder and containing a light emitting material that emits light due to plasma discharge by electromagnetic waves; A reflector disposed around the lamp to reflect light emitted from the lamp in a specific direction; In the electrodeless illuminating device which is coupled to the exit side of the reflecting mirror and blocks the leakage of electromagnetic waves and protects the lamp from the outside,

The lamp cover is characterized by consisting of a tubular cover body having a predetermined height so as to block the leakage of electromagnetic waves and reduce reflection of light, and a partition plate formed in a predetermined shape inside the cover body. A lamp cover structure of an electrodeless illuminator is provided.

Hereinafter, the lamp cover structure of the electrodeless lighting device of the present invention configured as described above will be described in detail with reference to an embodiment of the accompanying drawings.

Figure 3 is a perspective view showing a partially broken electrodeless lighting device having a lamp cover structure according to an embodiment of the present invention, Figure 4 is a longitudinal cross-sectional view of Figure 3, Figure 5 according to an embodiment of the present invention Front view of the lamp cover.

As shown in the drawing, the electrodeless lighting device having the lamp cover structure according to the present invention includes a resonance space 103 in which an antenna 102, which is an output part of the magnetron 101 that generates electromagnetic waves, receives power. It is inserted into the inlet side of the resonator 104 formed inside, and the electromagnetic wave generated from the magnetron 101 is connected to the resonance space 103 so that one end is connected to the antenna 102 inside the resonance space 103. An electromagnetic wave feeder 105 for guiding is provided, and a lamp 106 in which a light emitting material which emits light by a plasma formed by electromagnetic waves is coupled to the other end of the electromagnetic feeder 105. A reflector 107 is provided around the lamp 106 to reflect the light emitted from the lamp 106 in a specific direction, and at the exit side of the reflector 107, the leakage of electromagnetic waves is blocked. It is coupled from a lamp cover 108 to protect the lamps 106. The

The resonance space 103 formed inside the resonator 104 includes a vertical portion 103a open in the vertical direction so that the antenna 102 of the magnetron 101 can be inserted therein, and a vertical portion 103a. It consists of a horizontal part 103b formed in the horizontal direction so that it may communicate.

The electromagnetic feeder 105 is installed in the vertical direction inside the vertical portion 103a and has an end of the first conductor rod 111 connected to the antenna 102 and the first conductor rod 111. The second conductive rod 112 is disposed inside the horizontal portion 103b of the resonance space 103 so that the intermediate portion is connected to the lower portion.

The lamp 106 is a spherical shape having a predetermined space portion in which an encapsulating material emitting light by plasma is encapsulated. Preferably, the lamp 106 has a high light transmittance and extremely low dielectric loss, such as quartz.

In addition, the encapsulating material includes a light emitting material such as a metal, a halogen group compound, sulfur, or celen, which forms a plasma during operation of the lamp, and emits plasma, and argon (Ar) and xenon (Xe) to form a plasma therein at the initial stage of light emission. ) And an inert gas such as krypton (Kr), and a discharge catalyst material to facilitate initial discharge, such as mercury, to facilitate lighting, or to control the spectrum of light generated.

The reflector 107 is an elliptical shape having a predetermined curvature, and is installed between the electromagnetic wave feeder 105 and the lamp 106 and includes quartz or aluminum to move electromagnetic waves freely with the inside of the resonance space 103. It is made of the same dielectric material.

The lamp cover 108 has a tubular cover body 121 having a predetermined diameter and height h so as to block leakage of electromagnetic waves and reduce reflection of light, and the cover body 121 of the cover body 121. It is comprised by the partition plate 122 formed in the predetermined form inside.

The cover body 121 may have a cylindrical or rectangular tubular shape as in FIG. 6 according to the shape of the coupling portion of the resonator 104, and may form a partition plate 122 in a + shape. As shown in FIG. 7, the cover body 121 has a rectangular tubular shape, and the partition plate 122 is formed in a X shape, or as shown in FIG. 8, the cover body 121 has a rectangular tubular shape, and the partition plate ( 122) may be formed to be installed at equal intervals in the horizontal direction and pass through the central portion in the vertical direction, as described above, the shape of the lamp cover 108 is any shape that can block the leakage of electromagnetic waves and reduce the reflection of light It is also possible.

Hereinafter, the operation and effect of the electrodeless lighting device having a lamp cover structure according to the present invention configured as described above will be described.

Power is supplied to the magnetron 101 to generate an electromagnetic wave having high frequency energy in the magnetron 101, and the electromagnetic wave is emitted through the antenna 102 of the magnetron 101. Electromagnetic waves emitted through the electromagnetic wave feeder 105 are guided into the resonance space 103 of the resonator 104.

As described above, the electromagnetic wave guided to the resonator space 103 of the resonator 104 selects an appropriate resonant frequency while resonating, and the electromagnetic wave of the selected resonant frequency band discharges the inert gas enclosed in the lamp 106, and the discharge thereof. Heat generated by vaporizes the light emitting material to form a plasma, and the plasma emits light of high intensity by continuously maintaining the discharge by electromagnetic waves. This light is reflected to the front side by the reflector 107 to illuminate the required space.

Then, as described above, when the light is reflected by the reflector 107 to the front side, the leakage of the electromagnetic wave is blocked by the lamp cover 108 designed to have a suitable height to block the leakage of the electromagnetic wave, and the light is minimized in reflection. In the state is passed through the partition plate 122 of the lamp cover 108 to be illuminated forward.

As described in detail above, the lamp cover structure of the electrodeless lighting device of the present invention is a tubular cover body having a predetermined height so as to block leakage of electromagnetic waves and reduce reflection of light, and the cover body thereof. Consists of a partition plate formed in a predetermined shape inside, the electromagnetic wave resonating when the light is emitted from the lamp is prevented from leaking through the lamp cover, the light emitted from the lamp is mostly reflected through the partition plate without reflecting As a result, the luminous efficiency of the lighting device is improved.

Claims (3)

A magnetron for converting electrical energy into high frequency energy; A resonator in which an output portion of the magnetron is inserted at an inlet side and a resonant space in which electromagnetic waves resonate is formed inside; An electromagnetic feeder having one end connected to an output of the magnetron, for inducing electromagnetic waves generated from the magnetron into a resonance space; A lamp connected to the other end of the electromagnetic feeder and containing a light emitting material that emits light due to plasma discharge by electromagnetic waves; A reflector disposed around the lamp to reflect light emitted from the lamp in a specific direction; In the electrodeless illuminating device which is coupled to the exit side of the reflecting mirror and blocks the leakage of electromagnetic waves and protects the lamp from the outside, The lamp cover is characterized by consisting of a tubular cover body having a predetermined height so as to block the leakage of electromagnetic waves and reduce reflection of light, and a partition plate formed in a predetermined shape inside the cover body. Lamp cover structure of electrodeless lighting equipment. The method of claim 1, The cover body of the lamp cover is formed in a circular or rectangular shape, the partition plate is a lamp cover structure of the electrodeless lighting device, characterized in that formed in the "+" shape. The method of claim 1, The cover body of the lamp cover is formed in a square, the partition plate is formed of a plurality of partitions at equal intervals in the "x" shape or the horizontal direction and the lamp cover of the electrodeless lighting device, characterized in that formed to pass through the central portion in the vertical direction rescue.

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