KR101132757B1 - Led bulb - Google Patents

Abstract

The present invention provides an LED bulb. The LED bulb is a glass case made of a glass, the lower opening is formed, a predetermined space is formed therein, a half mirror coating layer having a predetermined light transmittance and a light reflectance is formed on the inner circumference thereof; A substrate installed in the glass case and formed of FR4, the substrate having a plurality of LEDs emitting light by receiving power from the outside; And a cover coupled to a lower end of the glass case and transmitting light emitted from the LEDs. Accordingly, the present invention can implement illumination to the surroundings simultaneously by increasing the reflection angle of the ambient light generated by the light emitted from the LEDs as well as the direct light emitted from the LEDs.

Description

LED Bulb {LED BULB}

The present invention relates to an LED light bulb, and to an LED light bulb that can simultaneously realize illumination to the surroundings by increasing the reflection angle of ambient light generated by the light emitted from the LEDs as well as the direct light.

Typically, a conventional incandescent light bulb uses a mechanical structure called a light exchanger to rotate a socket member installed with a plurality of incandescent light bulbs, thereby driving a motor mounted in the light exchanger in case of an incandescent light bulb that is currently in operation and automatically turns into a spare light bulb. It is configured to switch.

However, such incandescent bulbs require frequent checks and maintenance of the power supply unit due to inefficient use of the power source, and there is a problem that the administrators require frequent checks due to shortening of the endurance of the battery.

Accordingly, in recent years, light bulbs with LEDs having higher luminance than incandescent bulbs have been developed and used. The LED bulb has a plurality of LED modules for emitting light are installed in the bulb body, each LED module is designed to be electrically connected to the power supply of the control module to be operated by the power supplied from the battery.

In the conventional LED bulb, since the LED module is directly exposed to the outside, there is a problem that the LED bulb is easily broken when an impact is applied from the outside.

In addition, since the LED module is formed to be directly exposed to the outside, the light emitted from the LEDs is covered by the portions in which the LED modules are in contact with each other when the LED module is turned on.

In addition, since the light is not transmitted to the outside of the bulb body other than the area where the LEDs are irradiated, there is a problem that the brightness around the bulb is reduced. That is, since the light emission range of the light is narrowed, the luminous intensity is relatively lower than that of the lens unit of the LED module, and thus there is a problem that the luminous intensity of the entire light bulb is reduced.

SUMMARY OF THE INVENTION An object of the present invention is to provide an LED bulb capable of simultaneously illuminating the light emitted from the LED, as well as increasing the reflection angle of the ambient light generated by the light emitted from the LEDs to simultaneously illuminate the surroundings.

Another object of the present invention is to provide an LED bulb that can achieve self-heating by using a half mirror coating layer coated on the inner surface of the glass case without installing a separate heat dissipation mechanism.

Another object of the present invention is to provide a glass cover capable of covering the LEDs and a glass cover having a plastic cover and a plastic cover to protect the LEDs from the outside, and to form a pattern thereon to conform to the pattern. It is to provide an LED bulb that can easily illuminate the pattern to the outside.

In a preferred embodiment, the present invention provides an LED bulb.

The LED bulb is a glass case made of a glass, the lower opening is formed, a predetermined space is formed therein, a half mirror coating layer having a predetermined light transmittance and a light reflectance is formed on the inner circumference thereof; A substrate installed in the glass case and formed of FR4, the substrate having a plurality of LEDs emitting light by receiving power from the outside; And a cover coupled to a lower end of the glass case and transmitting light emitted from the LEDs.

Here, the half mirror coating layer is preferably formed by forming a metal deposition film on one surface of the synthetic resin-based sheet on which both surfaces are hard-coated, and drying the synthetic resin-based sheet on which the metal deposition film is formed for a predetermined time.

In addition, a first pattern having a predetermined shape is formed on the half mirror coating layer, and the first pattern is preferably formed to have a predetermined shape by etching the metal deposition film.

In addition, the cover is coupled to the glass case and the coupling means, the coupling means is a locking projection protruding on the lower end of the glass case, the locking groove is formed on the outer circumferential upper end of the cover to engage the engaging groove It is desirable to have.

In addition, the cover is coupled to the glass case by a coupling means, wherein the coupling means may be a grip member made of an elastic material that grips the outer circumference of the lower end of the glass case and a predetermined portion of the outer circumference of the cover.

Moreover, it is preferable that the said cover consists of either glass and plastics.

In addition, the cover is preferably provided with a plastic cover coupled to the lower end of the glass case and having an installation groove on one surface thereof, and a glass cover fitted into the installation groove.

Here, the plastic cover is preferably made of a translucent material.

In addition, it is preferable that a second pattern having a predetermined shape is formed on the inner surface of the cover.

The present invention increases the reflection angle of the ambient light generated by the light emitted from the LEDs as well as the direct light emitted from the LEDs, and has the effect of simultaneously realizing the illumination to the surroundings.

In addition, the present invention has the effect of achieving self-heat dissipation by using a half mirror coating layer coated on the inner surface of the glass case without installing a separate heat dissipation mechanism.

The present invention also provides a glass cover capable of covering the LEDs and a glass cover having a plastic cover and a plastic cover to protect the LEDs from the outside and to form a pattern thereon to form a pattern according to the pattern. It has an effect that can be easily illuminated on the outside.

1 is a perspective view showing the LED bulb of the present invention.
FIG. 2 is an exploded perspective view showing the LED bulb of FIG. 1. FIG.
3 is an exploded cross-sectional view showing the LED bulb of FIG.
4 is a cross-sectional view showing the LED bulb of FIG.
FIG. 5 is an enlarged partial cross-sectional view of a display symbol A of FIG. 3.
FIG. 6 is an enlarged partial cross-sectional view of a display B of FIG. 3.
7 is a cross-sectional view showing a coupling relationship between a glass case and a cover according to the present invention.
8 is a cross-sectional view showing a bonding relationship between the glass case and the glass and plastic mixing cover according to the present invention.

Hereinafter, with reference to the accompanying drawings to describe the LED bulb of the present invention.

The LED bulb of the present invention can be employed in an MR16 lighting bulb.

'형상으로 이루어질 수 있다. 물론, 상기의 형상 이외에 다수의 면을 갖는 형상으로도 이루어질 수 있다.1 to 5, the LED bulb of the present invention has a glass case 100 having a lower opening, made of glass, and having a half mirror coating layer 110 (see FIG. 5) formed on an inner circumferential surface thereof. The glass case 100 has a dome shape at the top and preferably has an opening at the bottom.

'Can be made in shape. Of course, in addition to the above shape may also be made of a shape having a plurality of surfaces.

The half mirror coating layer 110 is formed on the inner circumferential surface of the glass case 100 as described above. The half mirror coating layer 110 forms a metal deposition film 112 on one surface of the synthetic resin-based sheet 111 on which both surfaces are hard-coated, and the synthetic resin-based sheet 111 on which the metal deposition film 112 is formed for a predetermined time. It can be done by drying.

Here, the synthetic resin sheet 111 may be an acrylic resin or a PC resin.

In addition, a metal used in the metal deposition layer 112 may be a motor-driven metal such as aluminum, nickel, chromium. The metal deposition layer 112 may be deposited by a physical vapor deposition (PVD) process.

Here, the metal deposition layer 112 may serve as a conductive layer to conduct heat generated by the light emitted from the LEDs 210 to the outside, thereby performing its own heat dissipation function.

In addition, a first pattern 120 having a predetermined shape may be formed on the half mirror coating layer 110. The first pattern 120 may be formed to have a predetermined shape by etching the metal deposition layer 112.

Here, the first pattern 120 may be formed to protrude using a method of printing on the metal deposition film 112.

In this case, the first pattern 120 may increase the contact area with the air in the half mirror coating layer 110 that may substantially act as a heat dissipation layer, so that heat dissipation may be more efficiently performed.

On the other hand, the half mirror coating layer 110 has a predetermined light transmittance and light emissivity. Preferably, the thickness of the metal deposition layer 112 is adjusted so that the light transmittance may have a transmittance of 50% to the outside of the glass case 100.

In addition, the half mirror coating layer 110 may be formed such that the reflection angle reflecting the light emitted from the LEDs 210 in the glass case 100 back to the glass case 100 is wide at a predetermined angle. Can be.

2 to 4, the socket 130 is formed at the upper end of the glass case 100 configured as described above. The socket installation hole 131 is formed in the socket 130 to communicate with the inside of the glass case 100. In addition, the socket installation hole 131 is inserted into the socket 141 is installed. The socket 141 is provided with a pair of socket pin holes 141a penetrating up and down, and the socket pins 140 are inserted into the pair of socket pin holes 141a, respectively.

In addition, the glass case 100 is installed in a form in which the SMPS 300 and the substrates 200 on which the LEDs 210 are mounted are sequentially stacked.

3 and 4, first locking protrusions 301 are formed on the inner circumference of the glass case 100 to support the outer circumference of the SMPS 300. Here, first inlet holes 102 are formed on the outer circumference of the SMPS 300 to allow the first catching protrusions 301 to be drawn in. Therefore, after passing the first insertion holes 301 of the SMPS 300 through the first locking protrusions 101, the bottom surface of the SMPS 300 is supported by the first locking protrusions 102. The SMPS 300 may be installed in the glass case 100 so as to be possible. The SMPS 300 may receive power from an external source and apply power to the substrate 200.

In addition, the substrate 200 may be installed in the glass case 100 to be positioned below the SMPS 300. Here, second inlet holes 201 are formed in the outer circumference of the substrate 200 to allow the second catching protrusions 101 to be introduced therein. Therefore, after the second insertion holes 201 of the substrate 200 pass through the second locking protrusions 101, the bottom surface of the substrate 200 is supported by the second locking protrusions 101. The substrate 200 may be installed inside the glass case 100 so that the substrate 200 can be formed.

Here, reference numeral 142 denotes a wire electrically connecting the socket pin 140 and the SMPS 300.

The substrate 200 is made of FR4 formed of an epoxy material. Therefore, the substrate 200 may be implemented on both sides of the substrate. In addition, a plurality of LEDs 210 may be mounted on the bottom surface of the substrate 200. The LEDs 210 are disposed to face the lower opening of the glass case 100.

3 and 4, the cover 400 is installed at the lower end of the glass case 100 as described above.

The lower portion of the glass case 100 is formed with a cover fitting hole 100a in which the glass cover 400 according to the present invention may be inserted. Therefore, the glass cover 400 may be inserted into the cover fitting hole 100a and installed at the lower end of the glass case 100.

In addition, the glass cover 400 is fixed to the lower end of the glass case 100 is the grip of the elastic that can grip the outer peripheral portion of the lower end of the glass case 100 and the outer surface of the glass cover 400 The manner of using the member 900 can be applied.

Therefore, by installing the grip member 900 having the predetermined elasticity to surround the outer periphery of the lower end of the glass case 100, the glass cover 400 may be stably fixed in the cover fitting hole 100a. . Here, the grip member 900 may use an elastic material of silicon material having heat resistance.

In addition, the cover according to the present invention may be made of any one of the plastic cover 401 or the cover 402 used in combination of glass and plastic in addition to the glass cover 400 as described above.

Meanwhile, referring to FIG. 7, the glass cover 400 or the plastic cover 401 may be fixedly installed at the lower end of the glass case 100 through a separate coupling means 600.

Here, the coupling means 600 is coupled to the coupling protrusion 610 protruding from the bottom of the glass case 100, the outer periphery of the glass cover 400 is coupled to the coupling protrusion 610 is fitted It may be composed of a groove 620. For example, the coupling protrusion 610 may be divided into two branches, and the locking protrusion 611 may be formed at each end thereof. Therefore, when the engaging projection 610 divided into two branches is brought into close contact with each other when the engaging groove 620, the engaging projection 611 is a locking groove 621 formed inside the coupling groove 620. When two branches are opened, the locking protrusion 611 may be fitted into the locking groove 621.

In addition, the coupling protrusion 610 may be formed in the cover 400, the coupling groove 620 may be formed in the glass case 100.

In addition, the glass cover 400 may be implemented in a separate form from the glass case 100, but may be manufactured to be integral with each other.

In addition, a second pattern 500 having a predetermined pattern (for example, a floral pattern) is formed on the upper surface of the glass cover 400 (the surface of the side on which the LEDs 210 are disposed) by using haze printing. It may be formed. In this case, the pattern corresponding to the second pattern 500 (see FIG. 6) may be formed at a predetermined position by light emitted from the LEDs 210 at a predetermined position.

Here, the cover may be made of a plastic cover 401, in this case, the plastic cover 401 may be made of either translucent or transparent.

In addition, a second pattern 501 having a predetermined pattern (for example, a floral pattern) may be formed on the upper surface of the plastic cover 401 (the surface on which the LEDs 210 are disposed). In this case, the pattern corresponding to the second pattern 501 may be formed at a predetermined position by light emitted from the LEDs 210 at a predetermined position.

Meanwhile, referring to FIG. 8, the cover according to the present invention may be made of a mixed cover 402 of glass and plastic.

In this case, the cover 402 is a plastic cover 420 having a mounting groove 421 having an upper surface opened and dug to a predetermined depth, and a glass cover fitted into and fixed to the mounting groove 421 of the plastic cover 420. 410. Here, the glass cover 410 may be located inside the glass case 100.

 The cover 402 configured as described above may be coupled to each other by the glass case 100 and the coupling means 600.

Here, the coupling means 600 is formed on the coupling protrusion 610 protruding from the lower end of the glass case 100, the outer periphery of the plastic cover 420, the coupling protrusion 610 is coupled to the coupling It may be composed of a groove 620. Here, the coupling means 600 may be the same as mentioned above.

In addition, the coupling protrusion 610 may be formed in the plastic cover 420, and the coupling groove 620 may be formed in the glass case 100.

In addition, the plastic cover 420 may be made of either translucent or transparent.

In addition, a second pattern having a predetermined pattern (for example, floral pattern, etc.) by using haze printing on the upper surface of the glass cover 410 inserted into the seating groove 421 (the surface of the side on which the LEDs 210 are disposed). 502 may be formed. In this case, a pattern corresponding to the second pattern 502 may be formed at a predetermined position by light emitted from the LEDs 210 at a predetermined position.

Therefore, the present invention increases the angle of reflection with respect to the ambient light of the light emitted from the LEDs 210 by the half mirror coating layer 110 formed on the inner circumferential surface of the glass case 100 to simultaneously implement illumination to the surroundings. Has

In addition, the present invention can achieve self-heat dissipation by using a half mirror coating layer 110 coated on the inner surface of the glass case 100 without installing a separate heat dissipation mechanism.

In addition, the present invention includes a glass cover 400 that can cover the LEDs 210 and the glass cover 410 having a plastic cover 401 and the plastic cover 420 to the LEDs 210 ) And from the outside, by forming a pattern on them, it is possible to easily illuminate the pattern according to the pattern to the outside.

In addition, by manufacturing the glass case 100 on which the substrate 200 according to the present invention is installed, the manufacturing cost may be reduced.

On the other hand, the inside of the glass case 100 according to the present invention may be further filled with a filler (not shown) of the foam material containing the phosphor. Therefore, the filler may be filled in the space region except for the SMPS 300 and the substrate 200.

Therefore, when light is emitted from the LEDs 210 mounted on the substrate 200, the emitted light is emitted to the outside through the covers 400, 401, and 402 according to the present invention, as well as by the phosphor contained in the filler. Light may be further emitted to the outside through the glass case 100 made of a glass material in a state where the brightness of the light is further formed.

Therefore, since the light emitted from the LEDs 210 is further emitted through the glass case 100 in addition to the light emitted through the covers 400, 401, and 402, the degree of brightness of the LED bulb of the present invention toward the outer peripheral region is improved. You can.

100: glass case 101: second jamming projection
102: first projection projection 110: half mirror coating layer
120: first pattern 130: socket portion
131 socket mounting hole 140 socket pin
141: socket 141a: socket pin hole
200: substrate 201: second inlet hole
210: LED 300: SMPS
301: first entrance hole 400: glass cover
401: plastic cover 500,501,502: second pattern

Claims (9)

A glass case comprising a lower opening, a predetermined space formed therein, a half mirror coating layer having a predetermined light transmittance and a light reflectance on the inner circumferential surface, and having a predetermined thickness;
A substrate installed in the glass case and formed of FR4, the substrate having a plurality of LEDs emitting light by receiving power from the outside; And
Is coupled to the bottom of the glass case, including a cover for transmitting the light emitted from the LEDs,
The half mirror coating layer is formed with a first pattern protruding toward the inner space of the glass case,
LED bulb, characterized in that the filler containing the phosphor is filled in the glass case. The method of claim 1,
The half mirror coating layer,
An LED bulb, comprising: forming a metal deposition film on one surface of a synthetic resin sheet on which both surfaces are hard-coated, and drying the synthetic resin sheet on which the metal deposition film is formed for a predetermined time. The method of claim 2,
The first pattern having a predetermined shape is formed on the half mirror coating layer,
And the first pattern is formed to have a predetermined shape by etching the metal deposition film. The method of claim 1,
The cover is coupled to the glass case by a coupling means,
LED is characterized in that the coupling means has a locking projection protruding on the lower end of the glass case, and a locking groove formed on the outer circumferential upper end of the cover to engage the engaging projection. The method of claim 1,
The cover is coupled to the glass case by a coupling means,
The coupling means is an LED bulb, characterized in that the grip member of the elastic material to grip the outer peripheral portion of the lower end of the glass case and the outer peripheral portion of the cover. The method of claim 1,
The cover, LED bulb, characterized in that made of any one of glass and plastic. The method of claim 1,
The cover, the LED bulb characterized in that it comprises a plastic cover coupled to the lower end of the glass case and having an installation groove on one surface, and a glass cover fitted to the installation groove. The method of claim 7, wherein
LED bulb, characterized in that the plastic cover is made of a translucent material. The method of claim 1,
LED bulb, characterized in that a second pattern of a predetermined shape is formed on the inner surface of the cover.

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