KR20100096979A - Led lamp with many particular mirror - Google Patents

Abstract

PURPOSE: An LED(Light Emitting Diode) lamp is provided to easily vary the range of light irradiation by controlling the distance between a LED and a lens. CONSTITUTION: A plurality of LEDs are installed on a substrate. A lens(34) is arranged in the front of the LED in order to refract light which is emitted from the LED. A reflector(36) is arranged in the LED in order to reflect light which is emitted from the LED. A driving part supplies power to the LED. A body(24) stores the substrate and the driving part. A lamp base(26) is arranged in the bottom of the body. The lamp base receives power from a power supply part.

Description

LED lamp with multiple independent reflectors {LED LAMP WITH MANY PARTICULAR MIRROR}

The present invention relates to an LED lamp having a plurality of independent reflectors, and more particularly, in order to increase the reflection efficiency, a lens is disposed in front of the LED, and each reflector has an independent reflector for each LED to substantially increase the reflectance. The present invention relates to an LED lamp having a large number of independent reflectors that enable higher illumination even with power.

As is well known, an incandescent lamp is generally a light source that receives light by temperature radiation while the filament wire is heated to a high temperature when the filament wire is put in a glass sphere of vacuum, and the filament is thinned and evaporated at a high temperature. The mixture of argon and nitrogen is added to suppress evaporation to prolong life.

Ordinary incandescent lamps, which emit light close to natural light, can reduce eye fatigue and are easily removable in the socket. Since invented by Edison, it is one of the most widely used lighting lamps for a long time since the invention of Edison. There is a disadvantage that the heat efficiency is low because it is emitted as heat and only a part is used as light.

LED (light emitting diode) is a light source using the light emitting phenomenon generated when a voltage is applied to the semiconductor, which has been improved in brightness over the past several years to improve the lighting can be used for lighting, compared to conventional incandescent light bulbs Its power consumption is low and its life is long, bright and clear.

Recently, an LED lamp has been released for a general light bulb, which will be described in detail with reference to the accompanying drawings. 1 is a front sectional view showing an LED lamp according to a conventional embodiment.

Referring to this, the LED lamp 2 according to the conventional embodiment is a light emitting diode (LED) 18 as a light source, the LED 18 is a light emitting device that emits light when applied to the semiconductor compound, the power Consumption is only 20 ~ 30% compared to incandescent light bulb and has a long life, so once installed, there is a big advantage that there is no maintenance.

The number of LEDs 18 can be selected and used according to the amount of light required, and the power lines to be fixed to the substrate 16 and to be supplied to each LED 18 are printed in a pattern form to be connected to the power terminals of the respective LEDs 18. do.

In addition, a reflecting plate 20 is provided to surround the periphery of the LED 18 and to increase the brightness by reflecting the light generated from the LED 18 in front, and below the substrate 16. A heat sink is installed through the heat conductive adhesive member 14 to dissipate heat generated by the LED 18 to the outside. The thermally conductive adhesive member 14 is capable of attaching a heat sink to the substrate 16 to transfer heat generated from the substrate 16, that is, the LED 18, to the heat sink. It serves to convey.

The heat sink is in contact with the substrate 16 through the thermally conductive adhesive member 14 to release heat to the outside, and the first heat sink 10 is in contact with the first heat sink 10. And a second heat sink 12 for dissipating heat transferred to the sink 10. The second heat sink 12 is composed of an uneven portion so that heat can be released into the air.

A part of the first heat sink 10 and the second heat sink 12 as described above protects from being damaged by the impact of contact with the outside and a human hand contacts the heat sink 10, 12. The heat sinks 10 and 12 are structured to be accommodated in the body 4 in order to prevent accidental injuries that may be caused from heat generated by the heat sinks 10 and 12.

In addition, a driving unit 8 for operating the LED 18 is installed inside the body 4. The driver 8 may be composed of a constant voltage source and a constant current source to supply a stable voltage and current to the LED (18).

The lower end of the body 4 is provided with a light bulb base 6 which is electrically connected to the LED 18 inward through the driving unit 8 to supply driving power to the LED 18. The bulb base 6 has a cylindrical electrode formed on the outer circumferential surface by a screw type, and an electrode provided at the center of the cylindrical electrode via a cylindrical electrode and an insulator, and is screwed into a bulb socket (not shown). They are formed of an E26 standard base that contacts each electrode of the bulb socket to conduct electricity.

Therefore, it is possible to perform a sufficient function as a lamp having a high brightness LED 18 as a light source, it can be used semi-permanently through the efficient heat dissipation.

The LED lamp 2 according to the conventional embodiment having the above-described configuration is equipped with a plurality of LEDs 18 on the substrate 16, in order to generate sufficient illuminance, and a single unit around the LEDs 18. The reflecting plate 20 is surrounded and assembled, and the light generated from such an LED 18 is reflected by the reflecting plate 20 as shown by the dotted line.

That is, in the LED lamp 2 according to the conventional embodiment, a plurality of LEDs 18 are arranged at equal intervals on a substrate 16 having a flat panel structure, and the LED lamp 2 is generated by the lighting of the LEDs 18. The reflected light is reflected by the reflector 20 to increase the illuminance of the light source.

However, the reflection of the LED 18 by the reflector 20 is reflected only by the LED 18 located at the edge adjacent to the reflector 20, the LED 18 located in the center is the reflector Since reflection by 20 is hardly achieved, there is a problem that the reflection efficiency drops drastically.

That is, the LED lamp 2 according to the conventional embodiment has a long life and has the advantage of being able to produce the same illuminance with low power, but this is because the length of the reflector 20 cannot be configured to be infinitely long in front of the plurality of LEDs ( Due to the inability to reflect all the light from 18 through a single reflector 20, there is a problem that more power must be consumed in order to generate the same illuminance.

In addition, the LED lamp 2 according to the conventional embodiment is simply a form in which the LED 18 is attached to the substrate 16, there is no means for refracting the light of the LED 18 with the reflector 20 Therefore, this also caused a decrease in reflection efficiency.

In addition, the LED lamp 2 according to the conventional embodiment is mounted so as not to adjust the length of the lens mounted on the front of the LED 18, when the length of the lens and the LED 18 is fixed to the LED ( 18) the length of the survey that can be investigated is also fixed. However, there is a problem that the user needs a long distance lighting, and on the contrary, there is a user who needs a short distance lighting.

The present invention has been made in view of the above-described circumstances of the prior art, and the present invention is provided with a lens spaced apart in front of the LED in order to increase the reflection efficiency, and by having an independent reflector for each LED, the reflectance is greatly increased to equal power. It is an object of the present invention to provide an LED lamp equipped with a plurality of independent reflectors to ensure higher illuminance even when using.

It is another object of the present invention to provide an LED lamp equipped with a plurality of independent reflectors as long as it allows various users to have various irradiation lengths suitable for use by being able to adjust the separation distance from the lens with respect to the LED mounted on the substrate.

In order to achieve the above object, according to a preferred embodiment of the present invention a plurality of LEDs and a light source; A substrate on which a plurality of LEDs are fixed; A lens mounted separately in front of each LED to refract the irradiation light of the LED; A reflecting mirror mounted separately for each LED so as to surround the LED, and reflecting irradiation light of the LED; A driving unit having a constant voltage source and a constant current source to supply stable voltage and current to the LED; A body accommodating the substrate and the driving part while forming an external shape of a lamp; It is installed at the bottom of the body and consists of a light bulb base that receives power from a power supply source to supply power to the driving unit, a plurality of independent reflectors, characterized in that to increase the reflection efficiency through independent reflectors for each LED The provided LED lamp is provided.

Preferably, the LED is provided with a plurality of independent reflector LED lamps, characterized in that six LEDs are installed at equal intervals around the center of the LED.

Preferably, the reflector is configured for each LED is composed of a total of seven reflectors, each reflector is provided with an LED lamp having a plurality of independent reflectors, characterized in that formed to be interconnected.

Preferably, the lens is provided with an LED lamp having a plurality of independent reflectors, characterized in that fixed to the reflector.

Preferably, the body is provided with a LED lamp having a plurality of independent reflector, characterized in that a plurality of heat dissipation holes are formed on the outer periphery.

Preferably, the body is provided with a LED lamp having a plurality of independent reflectors, characterized in that a plurality of uneven heat sinks are repeatedly formed along the outer circumference of the outer periphery thereof.

Preferably, the LED is provided with a LED lamp having a plurality of independent reflectors, characterized in that a total of three LEDs are installed at equal intervals of 120 degrees.

Preferably, the reflector is configured for each LED is composed of a total of three independent reflectors, each reflector is provided with an LED lamp having a plurality of independent reflectors, characterized in that formed to be interconnected.

Preferably, the lens comprises a lens body in the form of a convex lens; A connecting portion connected to the lens body to be opened to both sides of the lens body; It is made of a fixed body connected to the end of the connection portion in the ground direction and the insertion hole formed therein, the reflector is a dome-shaped reflector body; A lens mounting hole to which a lens body is mounted by being circularly cut in the center of the reflector body; A connection part insertion groove which is cut from an upper end of the reflector body to a predetermined length and is inserted into the connection part of the lens; There is provided an LED lamp with a plurality of independent reflectors, characterized in that the projection projecting upward from the lower portion of the reflector body is composed of a coupling projection coupled to the insertion hole formed in the fixed body of the lens.

Preferably, the LED lamp is provided with a plurality of independent reflectors, characterized in that the irradiation distance can be changed by adjusting the separation distance between the lens and the LED.

LED lamp having a plurality of independent reflector according to the present invention is equipped with a separate reflector for each of the plurality of LED mounted on the upper surface of the substrate, the irradiation light can achieve a higher frequency of reflection, thereby improving the reflection efficiency It has the advantage of increasing the illuminance per same power, and the lens is mounted inside each reflector, so it is possible to expect higher reflection efficiency by refracting more radiation in the direction of the reflector.

In addition, the present invention has an advantage that the irradiation distance can be changed by adjusting the separation distance between the lens and the LED when the product is assembled.

Hereinafter, an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view showing the appearance of the LED lamp with a plurality of independent reflector according to an embodiment of the present invention, Figure 3 shows a LED lamp with a plurality of independent reflector according to an embodiment of the present invention 4 is a bottom plan view of an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention, and FIG. 5 is a view of an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention. 6 is a side cross-sectional view of an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention.

Referring to this, the LED lamp 22 is provided with a plurality of independent reflector according to an embodiment of the present invention, like a conventional LED lamp, a plurality of LEDs 42 are configured as a light source and the plurality of LEDs 42 The substrate 40 to which the is fixed is provided.

In particular, the LED lamp 22 is provided with a plurality of independent reflecting mirrors according to an embodiment of the present invention is individually mounted in front of each LED 42, the lens 34 for refracting the irradiation light of the LED 42 Is provided, each reflecting the periphery of the LED 42, each of the LEDs 42, respectively, is provided with a reflector 36 for reflecting the irradiation light of the LEDs 42.

That is, the LED lamp 22 is provided with a plurality of independent reflector according to an embodiment of the present invention, a plurality of LEDs 42 are mounted on the substrate 40 at equal intervals, for each LED 42 Independent reflectors 36 are mounted. Therefore, since the irradiation light generated by the LED 42 is irradiated forward through a larger number of reflections, the relative illuminance becomes higher even when the same power is applied.

Therefore, the conventional lamp in which a single reflector 20 is formed in a plurality of LEDs 18 (see FIG. 1) has a relatively small amount of irradiation light irradiated to the reflector 20 by the LED 18 configured at the center thereof. Although it is difficult to expect the effect through the present invention, since the independent reflector 36 for each LED 42 is mounted, it exhibits excellent reflection efficiency, thereby ensuring higher illuminance at the same power.

On the other hand, the LED lamp 22 is provided with a plurality of independent reflector according to an embodiment of the present invention is provided with a constant voltage source and a constant current source therein the drive unit 38 for supplying a stable voltage and current to the LED body The body 24 is accommodated in the inside of the body 24 and has a body 24 for accommodating the substrate 40 and the driving unit 38 while forming an external shape of a lamp. The body 24 is installed at a lower end of the body 24 and supplies power to the driving unit. 38) is composed of a light bulb base (26) receiving power from a power supply source to supply to.

At this time, the bulb base 26 is provided with a cylindrical electrode formed on the outer periphery of the screw type, the electrode is installed in the center of the cylindrical electrode via a cylindrical electrode and an insulator, and turned to the bulb socket (not shown) The electrodes are formed of an E26 standard base that contacts the electrodes of the bulb sockets to conduct electricity. However, the configuration of the bulb base 26 is well known, and thus detailed description thereof will be omitted.

On the other hand, the LED lamp 22 provided with a plurality of independent reflector according to an embodiment of the present invention is a configuration in which a plurality of LEDs 42 are attached to the substrate 40, the number of the LEDs 42 Although not limited, the LED 42 illustrated in one embodiment of the present invention has six LEDs 42 disposed at equal intervals around the center of the LEDs 42.

In addition, the reflector 36 is configured for each LED 42, so that a total of seven reflectors 36 are formed, and each reflector 36 is configured as an integral type connected to each other.

That is, the reflector 36 is made to be mounted for each LED 42, it is composed of a plurality of neighboring reflectors 36 and a plurality of bodies through a mold is configured to be detached in front of the LED 42. .

In addition, the lens 34 is mounted to the front of the LED 42 for each LED 42, preferably the lens 34 is fixed to a predetermined portion of the inner wall of each reflecting mirror 36, 34 is refracted by a predetermined refractive index while the light generated from the LED 42 is transmitted, causing more irradiated light to be deflected toward the reflector 36 and projecting the irradiated light forward.

On the other hand, the LED lamp 22 is provided with a plurality of independent reflector according to an embodiment of the present invention is further equipped with a protective glass plate 32 at the forefront of the body 24 is dust or other foreign matter is the LED 42 Do not flow into).

In addition, the body 24 has a plurality of heat dissipation holes 30 are formed on the outer circumference thereof, and preferably, the body 24 is made of an aluminum-based material having excellent heat transfer power. It is configured to quickly dissipate heat generated from inside.

In addition, since the body 24 is repeatedly formed along the outer circumference of the heat sink 28 having a plurality of concave-convex shapes on the outer circumference thereof, the body 24 can more quickly dissipate heat generated therein.

Hereinafter, an LED lamp having a plurality of independent reflectors according to another embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 7 is a perspective view illustrating an LED lamp having a plurality of independent reflectors according to another embodiment of the present invention, and FIG. 8 is a plan view illustrating an LED lamp having a plurality of independent reflectors according to another embodiment of the present invention. to be.

Referring to this, the LED lamp 50 having a plurality of independent reflectors according to another embodiment of the present invention has the same configuration as that of the first embodiment, and the plurality of LEDs 42 which are light sources similar to the conventional LED lamps. ), And a substrate (not shown) to which the plurality of LEDs 42 are fixed is provided.

In particular, the LED lamp 50 with a plurality of independent reflectors according to another embodiment of the present invention is mounted separately in front of each LED 42, the lens 60 for refracting the irradiation light of the LED 42 Is provided, each reflecting the periphery of the LED 42, each of the LEDs 42, respectively, is provided with a reflecting mirror 62 for reflecting the irradiation light of the LEDs 42.

The LEDs 42 are installed at intervals such as 120 degrees when a total of three LEDs 42 are viewed in a plane, and the reflectors 62 are configured for each LED 42 so that a total of three independent reflectors 62 are provided. ), And each reflecting mirror 62 is formed to be connected to each other.

That is, the LED lamp 50 provided with a plurality of independent reflectors according to another embodiment of the present invention is equipped with a plurality of LEDs 42 at equal intervals on the substrate, each reflecting the independent reflector ( 62) is installed. Therefore, since the irradiation light generated by the LED 42 is irradiated forward through a larger number of reflections, the relative illuminance becomes higher even when the same power is applied.

On the other hand, while forming the appearance of the lamp is provided with a body 52 for receiving the substrate and the drive unit (not shown), is installed at the lower end of the body 52 to supply power from the power supply source to supply power to the drive unit The receiving light bulb base is configured, and the light bulb base has a plug terminal contact type, and a terminal 58 formed of a positive electrode and a negative electrode is formed.

In addition, the lens 60 is mounted in front of the LED 42 for each LED 42. Preferably, the lens 60 is fixed to a predetermined portion of the inner wall of each reflecting mirror 62, and the lens 60 ) Is refracted by a predetermined refractive index while the light generated from the LED 42 is transmitted, so that more irradiated light is refracted in the direction of the reflector 62, and projects the irradiated light forward.

On the other hand, the LED lamp 50 is provided with a plurality of independent reflector according to an embodiment of the present invention has a cover 64 is further equipped with a protective glass plate on the front of the body 24 is dust or other foreign matter Do not flow into the LED (42).

In addition, the body 52 has a plurality of heat dissipation holes 56 formed on the outer circumference thereof, and preferably, the body 52 is made of an aluminum-based material having excellent heat transfer power. It is configured to quickly dissipate heat generated from inside.

In addition, since the body 52 has a plurality of uneven heat sinks 54 formed on the outer circumference of the body 52 repeatedly, the body 52 may dissipate heat generated therein more quickly.

Hereinafter, the configuration and operation for adjusting the separation distance between the lens and the LED included in the LED lamp having a plurality of independent reflectors according to an embodiment of the present invention.

9 is an enlarged exploded perspective view illustrating main parts of a lens included in an LED lamp having a plurality of independent reflectors according to an exemplary embodiment of the present invention.

Referring to this, the LED lamps 22 and 50 equipped with a plurality of independent reflectors according to an embodiment of the present invention can adjust the separation distance from the lens with respect to the LED mounted on the substrate, thereby making it suitable for various users. One LED lamp that has a long irradiation length.

To this end, looking at the lens 34 provided in the LED lamps 22 and 50 provided with a plurality of independent reflectors according to an embodiment of the present invention, the lens 34 has a convex lens body 110. Wow; A connection part 112 connected to the lens body 110 to be opened to both sides of the lens body 110; It is composed of a fixed body 114 is connected to the end of the connecting portion 112 in the ground direction and the insertion hole 116 is formed therein.

In addition, when the reflector 36 provided in the LED lamps 22 and 50 provided with a plurality of independent reflectors according to an exemplary embodiment of the present invention is turned upside down, the reflector 36 is shaped like a dome. A reflector body 102; A lens mounting hole 104 which is circularly cut in the center of the reflector body 102 to which the lens body 110 is mounted; A connection part insertion groove 106 which is cut from a top of the reflector body 102 to a bottom of a predetermined length and into which the connection part 112 of the lens 34 is inserted; It is composed of a coupling projection 108 is projected upward from the lower end of the reflector body 102 and coupled with the insertion hole 116 formed in the fixed body 114 of the lens 34.

Therefore, when assembling the LED lamps 22 and 50 with the plurality of independent reflectors according to the embodiment of the present invention, first, the reflector 36 is turned upside down as shown in FIG. The insertion hole 116 of the fixing body 114 is fitted to the coupling protrusion 108 protruding upward from a predetermined portion.

At the same time, while fitting the insertion hole 116 into the engaging projection 108, while fitting the connecting portion 112 formed on both sides of the lens 34 is inserted into the connecting portion insertion groove 106 formed in the reflector body 102. The lens 34 and the reflector 36 are assembled. This can also be confirmed through the mounting portion A shown in FIG. 6.

As a result, in the present invention, in order to adjust the separation distance between the LED 42 mounted on the substrate and the lens 34, the connector 112 constituting the lens at the time of manufacture of the product is formed relative to the fixture 114. Are manufactured by differently manufacturing them, and if the configuration of the configuration of the connector 112 with respect to the fixture 114 is configured in various ways, the user selects the lens suitable for the use of the lamp, that is, the irradiation length of the desired lamp, and then assembles it. This will allow you to adjust the irradiation length of the lamp.

10A and 10B are side cross-sectional views illustrating a mounting state of a lens included in an LED lamp having a plurality of independent reflectors according to an exemplary embodiment of the present invention.

Referring to this, the LED lamps 22 and 50 provided with a plurality of independent reflectors according to the embodiment of the present invention respectively form the position of the connector 112 with respect to the fixture 114 of the lens 34. By fitting the fixture 114 to the coupling protrusion 108 formed on the reflector body 102 by different, the coupling position of the fixture 114 is the same, but the formation of the connector 112 connected to the fixture 114 Since the positions are different from each other, the lens body 110 connected to the connector 112 is different from each other with respect to the LEDs 42 at the lower ends thereof. If the appropriate lens 34 is selected, the distance between the lens 34 and the LED 42 can be adjusted.

Therefore, the present invention allows the LED lamp to have the desired irradiation length by selecting the appropriate lens 34 appropriate for the place of use of the lamp, that is, the irradiation length of the desired lamp.

On the other hand, the LED lamp provided with a plurality of independent reflector according to an embodiment of the present invention is not limited to the above embodiment only, various modifications are possible within the scope without departing from the technical gist.

1 is a front sectional view showing an LED lamp according to a conventional embodiment,

Figure 2 is a perspective view showing the appearance of the LED lamp with a plurality of independent reflector according to an embodiment of the present invention,

3 is a plan view showing an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention,

4 is a bottom view showing an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention,

5 is a side view showing an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention,

6 is a side cross-sectional view showing an LED lamp having a plurality of independent reflectors according to an embodiment of the present invention;

7 is a perspective view illustrating an LED lamp having a plurality of independent reflectors according to another embodiment of the present invention;

8 is a plan view showing an LED lamp having a plurality of independent reflectors according to another embodiment of the present invention,

9 is an enlarged exploded perspective view illustrating main parts of a lens included in an LED lamp having a plurality of independent reflectors according to an exemplary embodiment of the present invention;

10A and 10B are side cross-sectional views illustrating a mounting state of a lens included in an LED lamp having a plurality of independent reflectors according to an exemplary embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

22: LED lamp, 24: body,

26: bulb base, 28: heatsink,

30: heat radiator, 32: protective glass plate,

34: a lens, 36: a reflector,

38: driving part, 40: substrate,

42: LED.

Claims (10)

A plurality of LEDs as light sources; A substrate on which a plurality of LEDs are fixed; A lens mounted separately in front of each LED to refract the irradiation light of the LED; A reflecting mirror mounted around each of the LEDs, each reflecting the irradiation light of the LED; A driving unit having a constant voltage source and a constant current source to supply stable voltage and current to the LED; A body accommodating the substrate and the driving part while forming an external shape of a lamp; It is installed at the bottom of the body and consists of a light bulb base that receives power from a power supply source to supply power to the driving unit, a plurality of independent reflectors, characterized in that to increase the reflection efficiency through independent reflectors for each LED Equipped LED lamp. According to claim 1, wherein the LED is a LED lamp having a plurality of independent reflectors, characterized in that the six LEDs are installed at equal intervals around the center of the LED. The LED lamp having a plurality of independent reflectors according to claim 1, wherein the reflectors are configured for each LED, so that a total of seven reflectors are formed, and each reflector is connected to each other. The LED lamp of claim 1, wherein the lens is fixed to a reflector. The LED lamp of claim 1, wherein the body has a plurality of heat dissipation holes formed at an outer circumference thereof. The LED lamp having a plurality of independent reflectors according to claim 1, wherein the body has a plurality of uneven heat sinks formed on the outer circumferential edge of the body. According to claim 1, wherein the LED is a LED lamp having a plurality of independent reflectors, characterized in that a total of three LEDs are installed at equal intervals 120 degrees. The LED lamp having a plurality of independent reflectors according to any one of claims 1 to 7, wherein the reflectors are configured for each LED so that a total of three independent reflectors are formed, and each reflector is connected to each other. . The lens assembly of claim 1, wherein the lens comprises: a lens body in the form of a convex lens; A connecting portion connected to the lens body to be opened to both sides of the lens body; It is made of a fixed body connected to the end of the connecting portion in the ground direction and the insertion hole formed therein, The reflector is a reflector body in the form of a dome; A lens mounting hole to which a lens body is mounted by being circularly cut in the center of the reflector body; A connection part insertion groove which is cut from an upper end of the reflector body to a predetermined length and is inserted into the connection part of the lens; LED lamp having a plurality of independent reflector, characterized in that it comprises a coupling projection which is projected upward from the lower end of the reflector body and coupled to the insertion hole formed in the fixed body of the lens. 10. The method of claim 9, wherein the fixture is configured to configure the position of the connector is formed integrally on one side wall of the fixture, respectively, so that the irradiation distance can be changed by adjusting the separation distance between the lens and the LED. LED lamps equipped with a plurality of independent reflectors.

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