KR20210030062A - LED lamps and lenses for indirect illumination ceilings - Google Patents

Abstract

The present invention relates to a LED lamp and lens for an indirect irradiation ceiling lamp with a limited irradiation range that a light source generated from a LED is collected at a limited location and evenly distributed so that a LED light source is evenly diffused from a reflector formed on a ceiling lamp to the floor. In front of a light emitting element constituting the LED lamp, R1 from the top to the center line and R2 from the center line to the bottom of the front side form lenses with different refraction angles integrally to uniformly spread the distribution of the irradiated light. At the same time, the irradiation range is limited. Here, in the front of the lens, the R1 from the top to the center is R14.74, and the R2 from the center to the bottom is R5.4 so that the light refracted and irradiated is upwardly irradiated in a range of 22° a from horizontal line to upward.

Description

LED lamps and lenses for indirect illumination ceilings

The present invention relates to an LED lamp and a lens for indirectly irradiated ceiling lamps having a limited irradiation range, and in detail, the light source generated from the LED is collected at a limited location and evenly sprayed so that the LED light source is evenly diffused from the reflector formed on the ceiling lamp to the floor. It relates to LED lamps and lenses for indirect irradiation ceiling lamps with limited irradiation scope.

In general, LED light sources are widely used as display products of various electronic products because they show great advantages in processing speed, power consumption, and lifespan due to the characteristics of semiconductors. Recently, as products with high luminance have been developed, they are in the spotlight as high-tech lighting sources.

In particular, a lamp using an LED light source is in the spotlight as an efficient light source due to a lower power consumption than a conventional light bulb, and the LED has an advantage of being able to reduce management and maintenance costs such as replacement costs due to its excellent durability.

In accordance with this trend, researches on luminaires using an LED light source are being actively conducted in recent years. A review of the patent documents for this is as follows.

Patent application No. 10-2007-0118549 (2007.11.20) is a light emitting unit that emits irradiation light; A first lens unit configured to transmit irradiation light emitted from the light emitting unit in one direction; An upper reflector reflecting the irradiated light transmitted through the first lens unit; A second lens unit for transmitting the irradiation light reflected by the upper reflection unit; And a heat radiating part for cooling the light emitting part, wherein the radiating part includes a water jacket for receiving cooling water therein. Since both the front and rear widths and the upper and lower widths of the entire module are reduced, the size can be significantly reduced, and accordingly, its weight can be significantly reduced. It not only increases the degree of freedom in structure and design design, but also provides an effect of reducing the overall weight of the lighting device and the vehicle. Patent Application No. 10-2009-0063406 (2009.07.13) is a U-shaped cover having an incision at the top; A metal body fitted in the cutout portion of the cover to radiate heat generated during LED light emission; It is formed protruding from the lower part of the metal body located inside the cover to prepare the installation place of the printed circuit board in which the LEDs are arranged, and the heat generated during LED light emission is first radiated, and the remaining heat is radiated by the metal body second. Protrusions that were made to evangelize; LED installed on the side of the protrusion to irradiate light toward the side of the cover; A reflective layer installed on the inner surface of the cover to which the LED light is irradiated to form indirect lighting by reflecting the LED light toward the lower portion of the cover; And a cap member having terminals connected to the fluorescent lamp socket and installed at both open ends formed by a metal body and a cover to supply power to the LED, thereby removing glare by indirectly illuminating the LED light. LED fluorescent lamps are provided that can eliminate fatigue. Patent Application No. 10-2010-0097448 (2010.10.06) relates to an LED headlamp for a vehicle that is mounted on the front of a vehicle and irradiates light to the front, including: a headlamp case; LED installed on the inner side of the headlight case; And a lens installed on the front side of the LED to focus light emitted from the LED and irradiate it forward. Including, the lens is a condensing unit for focusing and irradiating some of the light emitted from the LED forward, a shield unit that reflects some of the light emitted from the LED to one side, and the light reflected from the shield unit is a vehicle A headlight case including an irradiation unit to be irradiated to the front of the vehicle; LED installed on the inner side of the headlight case; And a lens installed on the front side of the LED to focus light emitted from the LED and irradiate it forward. Including, wherein the lens provides a vehicle LED headlight including a shield unit that reflects the light emitted from the LED to one side, and an irradiation unit that allows the light reflected from the shield unit to be irradiated to the front of the vehicle, By reflecting the light emitted from the light source of the light source, the upper irradiation of the light is blocked, and the reflected light is irradiated to the front of the vehicle using the total reflection phenomenon of the light, thereby improving light efficiency. Patent Application No. 10-2012-0147982 (2012.12.18) is a side-emitting type light-emitting diode that can reduce the overall volume to reduce material cost, and improve light efficiency by considering the light source of the light-emitting diode as a surface light source. A lens for a side-emitting type LED, wherein the lens for a side-emitting type LED emits light emitted from a light-emitting diode (LED) to the side, wherein the light emitted from the light-emitting diode is A bottom surface provided with an incidence surface; An upper surface for totally reflecting light incident directly from among the light incident on the incident surface; And a side that connects the bottom surface and the upper surface, and exits the light directly incident from the light incident on the incident surface and the light totally reflected from the upper surface; wherein the incident surface includes an optical axis of the light emitting diode. In order to reduce the height of the lens, the light emitted from the light emitting diode is refracted in a direction away from the optical axis and incident on the upper surface, and is connected to the central region, and is connected to the width (or radius) of the lens. In order to reduce ), the light emitted from the light-emitting diode is refracted in a direction closer to the optical axis to be incident on the upper surface. Patent application No. 10-2013-0038091 (2013.04.08) reduces the overall volume to reduce material cost, and has a refracting part on the side of the plane so that light emitted to the side is a tangential component of the lens. It relates to a side emission type light emitting diode lens capable of spreading the light emitted from the light emitting diode more evenly as a whole by dispersing the light emitted from the light emitting diode as a whole, and a side emission emitting light emitted from the light emitting diode (LED) to the side. A lens for a light-emitting diode, comprising: a bottom surface provided with an incidence surface on which light emitted from the light-emitting diode is incident; An upper surface reflecting light incident on the incident surface; A side surface from which light reflected from the top surface exits; And a refracting part provided on an outer circumferential surface of the side surface and refracting the light emitted to the side surface in a circumferential direction to emit light. Patent Application No. 10-2015-0130429 (2015.09.15) At least one LED with a diffusion lens is formed on the upper surface, and at least one substrate with a control circuit for controlling the LED is formed on the outer peripheral surface in the vertical direction. Body to be installed; And at least one asymmetric lens formed in an aspheric shape so as to be formed to cover the diffusion lenses at intervals corresponding to each of the LEDs and radiate from the LED to change the emission angle of light incident through the diffusion lens. And a package consisting of a plurality of fastening portions coupled with lens fixing portions formed on the body on both sides, wherein the incident surface of the asymmetric lens provided in the package is radiated from the LED and light passing through the diffusion lens is incident. The surface is formed in a hemispherical shape symmetrical with respect to the horizontal center line (H) of the center of the LED, and the thickness of the asymmetric lens is changed by the asymmetric lens, so that the main light of the emitted light (A) is the LED. The lower part is formed thicker than the upper part based on the horizontal center line (H) in the horizontal direction so that it is located below the main light of the light (A) that is radiated from the diffuser lens and passes through the diffuser lens, and the main light of the asymmetric lens is irradiated vertically. Asymmetric, characterized in that the radiation angle of the light (A) in the direction is 10 degrees to 50 degrees below the horizontal center line (H), and the radiation angle of the light (A) in the horizontal direction irradiated by the daylight is 60 degrees to 130 degrees. An LED lighting device employing a lens, comprising: a body in which a plurality of LEDs are integrated on an outer circumferential surface; And an asymmetric lens corresponding to at least one of the plurality of LEDs to change the emission angle of light emitted from the LED, wherein the asymmetric lens is formed thicker in the lower portion than in the upper portion based on the center line in the horizontal direction of the LED. It is to provide a lighting device employing an asymmetric lens that changes the main light of light whose emission angle is changed by the lens to be positioned below the main light of light emitted from the LED.

The present invention is provided in order to solve the conventional problems as described above, and irradiation of light by integrally configuring a light emitting device with a front surface from the top to the center line and from the center line to the bottom with different refraction angles of light. Indirect irradiation with limited scope of irradiation Indirect irradiation LED lamps and lenses for ceiling lamps are supplied so that the bottom surface of the ceiling lamp is composed of a reflector, and the light emitted from the LED lamp is reflected by the reflector of the ceiling lamp and diffuses into the room. Its purpose is to make the ceiling light for home use indirect lighting.

In order to solve the above problems, the present invention integrally comprises a lens in which R1 from the top to the center line and R2 from the center line to the bottom in front of the light emitting device constituting the LED lamp have different refraction angles of light. An LED lamp for indirectly irradiated ceiling lamps with a limited irradiation range is constructed to uniformly diffuse the distribution of the irradiated light and at the same time limit the irradiation range, where the front of the lens is R1 from the top to the center and R1 is R14.74. R2, which is from the center to the bottom, forms R5.4 so that the light is refracted so that the irradiated angle is irradiated upward in the range of 22˚ from the horizontal to the top.

As described above, the LED lamps and lenses for indirectly irradiated ceiling lamps that have limited the irradiation range according to the present invention collect light sources generated from the LEDs at a limited location and spray them evenly so that the LED light source is evenly diffused from the reflector formed in the ceiling lamp to the floor. Thus, it is a novel invention having the effect of configuring a home ceiling lamp as an indirect lighting lamp so that the light emitted from the LED lamp is reflected by the reflector of the ceiling lamp and diffused into the room.

1 is a schematic diagram illustrating the overall configuration of the present invention.
Figure 2 is an exemplary view of the projection state of light of the present invention.
Figure 3 is an exemplary view of another configuration state of the lamp that is the main part of the present invention.
Figure 4 is an exemplary embodiment of the present invention.

The configuration of the present invention will be described in detail with reference to the accompanying drawings.

A lens 120 in which R1 from the top to the center line and R2 from the center line to the bottom in front of the light emitting device 111 configured in the LED module 110 constituting the LED lamp 100 have different refraction angles of light. ) Is configured to be in close contact with each other to uniformly diffuse the distribution of the irradiated light and at the same time to construct an LED lamp for indirect irradiation ceiling lamps with a limited irradiation range to limit the irradiation range.

At this time, the lens 120 forms a circular jaw 121 on the outer periphery of the light emitting device at the rear end, and R1 from the top to the center of the front surface constitutes R14.74, and R2 from the center to the bottom is R5.4. When the light is refracted and the irradiated angle is configured to be irradiated upward in a range of 22 degrees from the horizontal to the top, the coupling frame 130 is tightened with bolts so that the light-emitting element 111 formed in the LED module 110 is in close contact with the front. Sliding occurs in the inclined portion 122 and the rear end of the lens 120 is in close contact with the light emitting device 111 to form one LED lamp 100.

That is, in the lens 120, R1 from the top of the front to the center forms R14.74, and R2 from the center to the bottom forms R5.4, so that the irradiated angle of light is refracted upwards in a range of 22° from the horizontal to the top. Organize to investigate.

Hereinafter, an exemplary embodiment of the present invention will be described.

The luminaire body 10 is formed in a square or circular shape, and indirect irradiation using the reflection of light The light irradiation direction on the lamp installation part 12 of the LED ceiling lamp protrudes high and the center constituting the luminaire body 10 protrudes high. It is coupled to irradiate the reflector 30 having a configuration inclined toward the frame 11.

In this way, the LED lamp 100 of the present invention coupled to the ceiling lamp has a lens 120 integrally configured in front of the light emitted from the LED module 110, the light emitting device 111, R1 from the top to the center is R14.74. R2, which is from the center to the bottom, forms R5.4 and refracts differently from R1 so that it is evenly distributed and irradiated in a 22° range from the horizontal to the reflector 30 side.

Here, the front of the lens 120 is divided into R1 and R2 on the upper side and the lower side with the center as a boundary, so that the refraction angle of the light is configured differently. The purpose is to maximize the efficiency of scattering light to the floor and to respond to the configuration so that the center protrudes in consideration of aesthetics.

In this way, the LED lamp 100 using the lens 120, which is relatively evenly distributed due to the limited irradiation range, is installed to irradiate only with the reflector 20 of the luminaire body 10 so that the light irradiated to the reflector 30 is reflected. It diffuses into the room and completes an indirect irradiation LED ceiling light using a lens with a limited irradiation range.

For reference, the reflecting mirror 30 is configured so that the curve becomes a gentle reflection angle toward the outer frame 11 from the center, but the height of the protrusion 31 in the center of the reflecting mirror 30 is 20 mm, and the light of the LED lamp is irradiated from the center. When the distance to the last position on the outer side is 130mm, the projecting height of the reflector at 1mm distance from the center is 18.5mm, the height at 3mm distance is 15.6mm, the height at 5mm distance is 14.1mm, the height at 7mm distance is 13.1mm, the height at 9mm distance is 12.2mm, The height of the 12mm distance is 11.2mm, the height of the reflector at 16mm distance is 10mm, the height at 20mm distance is 9mm, the height at 25mm distance is 8mm, the height at 30mm distance is 7.1mm, the height at 37mm distance is 6.1mm, the height at 45mm distance is 5mm, 55mm The height of the distance is 4mm, the protrusion height of the reflector at 67mm distance is 3mm, the height at 82mm distance is 2mm, the height at 100mm distance is 1mm, the height at 114mm distance is 0.5mm, the height at 120mm distance is 0.3mm, and the height at 130mm distance is 0mm. to be.

The present invention is to be used indispensably in implementing the LED indirect, etc. as a ceiling for home, and it will be said that the industrial use value is great.

10: luminaire body 11: outer frame 12: lamp installation part
30: reflector 31: protrusion
100: LED lamp 110: LED module 111: light emitting device
120: lens 121: round jaw 122: inclined portion
130: combination frame

Claims (3)

A lens 120 in which R1 from the top to the center line and R2 from the center line to the bottom in front of the light emitting device 111 configured in the LED module 110 constituting the LED lamp 100 have different refraction angles of light. ) In close contact with each other to uniformly diffuse the distribution of the irradiated light and at the same time limit the irradiation range. The method of claim 1,
The lens 120 forms a circular jaw 121 on the outer periphery of the light emitting device at the rear end, and R1 from the top to the center of the front surface constitutes R14.74, and R2 from the center to the bottom constitutes R5.4 for light. Irradiation range, characterized in that the irradiated angle is configured to irradiate upward in a range of 22˚ from horizontal to the top, and combined with a coupling frame 130 so as to be integrally in close contact with the front of the light emitting device 111 configured in the LED module 110 Indirect irradiation limited to the LED lamp for ceiling lamps. In the lens 120 that induces refraction of light by integrally mounted in front of the LED lamp 100 to which light is irradiated,
In the lens 120, R1 from the top to the center of the front surface constitutes R14.74, and R2 from the center to the bottom constitutes R5.4, so that the irradiated angle is irradiated upward in a range of 22 degrees from the horizontal to the top. An LED lamp lens for indirect irradiation ceiling lamps having a limited irradiation range, characterized in that the irradiation range is limited.

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