KR20210115171A - LED lamp for ceiling and LED lamp lens - Google Patents

Abstract

The present invention relates to an LED lamp for a ceiling light in which a light source generated from an LED light emitting lamp is collected so as not to leak to the outside and evenly distributed to a limited location, and a lens constituting the same. The LED lamp for a ceiling light includes: a lens; an LED module which constitutes a light emitting lamp; and a lamp body chassis which forms a module coupling part coupling the LED module and a lens coupling part coupling the lens, allows a pressing protrusion to press a coupling wing of the lens and a contact surface to come in close contact with the lateral side of the lens at the same time, and is continuously and repeatedly molded left and right to form an installation groove so as to be easily attached to a lighting device.

Description

LED lamp for ceiling and a lens constituting the same {LED lamp for ceiling and LED lamp lens}

The present invention relates to an LED lamp for a ceiling lamp and a lens constituting the same, and in detail, it is an improved invention of Patent Application No. 10-2019-0111541, which was previously invented and applied by the person himself, and a light emitting lamp receiving groove is provided on the back of the lens. LED lamp for ceiling lamp that protects the LED light-emitting lamp by forming the LED module in close contact with the lamp body chassis to facilitate heat dissipation. and to a lens constituting the same.

In general, LED light sources are widely used as display products for 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 a high-tech light source for lighting.

In particular, a lamp using an LED light source has been spotlighted as an efficient light source due to its low power consumption compared to conventional light bulbs.

According to this trend, recent studies on luminaires using LED light sources are being actively conducted, and the patent literature on this is as follows.

Patent Application No. 10-2007-0118549 (2007.11.20) discloses a light emitting unit that emits irradiation light; a first lens unit for transmitting the irradiated light emitted from the light emitting unit in one direction; an upper reflector for reflecting the irradiated light passing through the first lens unit; a second lens unit for transmitting the irradiated light reflected by the upper reflecting unit; and a heat dissipating unit for cooling the light emitting unit, wherein the heat dissipating unit includes a water jacket accommodating 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 considerably miniaturized, and the weight thereof can be reduced accordingly. It not only increases the degree of freedom in designing the structure and design, but also provides the effect of reducing the overall weight of the lighting device and the vehicle. Patent Application No. 10-2009-0063406 (2009.07.13) discloses a U-shaped cover having a cutout on the top; a metal body fitted to the cutout of the cover to dissipate heat generated when the LED emits light; It is formed to protrude from the lower part of the metal body located inside the cover to provide an installation place for the printed circuit board on which the LEDs are arranged. protrusions made to be inverted; 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 achieve indirect lighting by reflecting the LED light toward the lower side of the cover; and a cap member having a terminal connected to the fluorescent lamp socket and installed at both ends of the opening formed by the metal body and the cover to supply power to the LED, thereby eliminating the glare phenomenon by indirectly illuminating the LED light and reducing eye damage. An LED fluorescent lamp is provided to 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 forward, and includes a headlamp case; LED installed on one side of the inside of the headlight case; and a lens installed on the front side of the LED to focus the light emitted from the LED and irradiate it forward. Including, wherein the lens includes a light condensing unit for focusing and irradiating some of the light rays emitted from the LED to one side, a shield unit reflecting some of the light rays emitted from the LED to one side, and the light reflected from the shield unit is a vehicle a headlight case including an irradiating part to be irradiated to the front of the; LED installed on one side of the inside of the headlight case; and a lens installed on the front side of the LED to focus the light emitted from the LED and irradiate it forward. Including, wherein the lens provides an LED headlamp for a vehicle comprising a shield portion for reflecting the light emitted from the LED to one side, and an irradiation portion for irradiating the light beam reflected from the shield portion to the front of the vehicle, the vehicle headlight The light efficiency can be improved by reflecting the light emitted from the light source of the light source to block the upper irradiation of the light beam, and allowing the reflected light beam to be irradiated to the front of the vehicle using the total reflection phenomenon of the light beam. Patent Application No. 10-2012-0147982 (2012.12.18) discloses a side emission type light emitting diode that can reduce the overall volume and reduce material costs, and can improve light efficiency by considering the light source of the light emitting diode as a planar light source It relates to a lens for a side emission type light emitting diode, the lens for a side emission type light emitting diode is a lens for a side emission type light emitting diode that 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 incident surface; an upper surface for total reflection of the directly incident light among the light incident on the incident surface; and a side connecting the bottom surface and the upper surface, from which the light directly incident among the light incident on the incident surface and the light totally reflected from the upper surface are emitted; the incident surface including the optical axis of the light emitting diode and a central region for refracting the light emitted from the light emitting diode in a direction away from the optical axis to make it incident on the image plane so as to reduce the height of the lens; ) by refracting the light emitted from the light emitting diode in a direction close to the optical axis to be incident on the upper surface. Patent Application No. 10-2013-0038091 (2013.04.08) discloses that the material cost can be reduced by reducing the overall volume, and a refracting part is provided on the side surface on a plane to transmit the light emitted to the side in the tangential component of the lens. It relates to a lens for a side emission type light emitting diode that can more evenly spread the light emitted from the light emitting diode as a whole by dispersing it into A lens for a light emitting diode, comprising: a lower surface provided with an incident surface on which light emitted from the light emitting diode is incident; an upper surface for reflecting the light incident on the incident surface; a side from which light reflected from the upper surface is emitted; and a refracting unit provided on the outer circumferential surface of the side surface to refract the light emitted to the side surface in a circumferential direction on a plane to emit the light. Patent Application No. 10-2015-0130429 (2015.09.15) At least one LED having a diffusion lens is formed on the upper surface and at least one substrate having a control circuit for controlling the LED on the lower surface is formed on the outer peripheral surface in the vertical direction body to be installed; and at least one asymmetric lens formed in an aspherical shape so as to cover the diffusion lens at a distance corresponding to each of the LEDs and to be emitted by changing the radiation angle of light emitted from the LED and incident through the diffusion lens and a package comprising a plurality of fastening coupling parts coupled to the lens fixing parts formed on the body on both sides; the incident surface of the asymmetric lens provided in the package is radiated from the LED and the light passing through the diffusion lens is incident The surface is formed in a symmetrical hemispherical shape with respect to the horizontal center line (H) of the center of the LED, and the thickness of the asymmetric lens is the main light of the light (A) emitted by changing the radiation angle by the asymmetric lens. The lower part is 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) emitted through the diffusion lens and incident, and the main light of the asymmetric lens is irradiated vertically. Asymmetrical, characterized in that the radiation angle of the light A in the direction is 10 to 50 degrees below the horizontal center line H, and the radiation angle of the light A in the horizontal direction irradiated by the main light is 60 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 radiation angle of light emitted from the LED, wherein the asymmetric lens is formed thicker at the lower part than the upper part with respect to 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 the light whose radiation angle is changed by the lens to be positioned below the main light of the light emitted from the LED.

The present invention is an improved invention of Patent Application No. 10-2019-0111541, which was invented and applied for by the person himself, in order to solve the above problems of the prior art. The purpose of this is to protect the LED module, make it easy to dissipate heat by attaching the back surface of the LED module to the lamp body chassis, and to collect the light source emitted from the light emitting lamp of the LED module so that it does not leak to the outside and spray it evenly in a limited location.

In order to achieve the above object, the present invention includes: a lens configured to project forward without leaking or scattering light emitted from a light emitting lamp of an LED module; an LED module accommodated in the light emitting lamp receiving groove of the lens to constitute a light emitting lamp emitting light; The module coupling part for coupling the LED module and the lens coupling part for coupling the lens are formed, and when the bending part and the wedge groove are formed, and the wedge piece is forcibly coupled to the wedge groove, the pressing jaw forms the coupling wing of the lens by the bending of the bending part. The lamp body chassis, the LED module, and the lens are configured so that the contact surface is in close contact with the side of the lens at the same time as pressing, and the lamp body chassis is formed by continuously repeating molding left and right to form an installation groove for easy installation on the luminaire. Combined integrally to form an LED lamp for a ceiling lamp.

And the lens is continuously long from side to side, and the front end surface forms a light transmitting surface with a plane perpendicular to the center line, and both sides are formed in the shape of a front and rear constriction at an angle of 30° and an angle of 60°. , at the rear end, coupling wings for pressing the LED module are formed on both sides by coupling to the lamp body chassis, and a light emitting lamp receiving groove into which the light emitting lamp of the LED module is inserted is formed, and the radius is R1. A five-person spherical convex lens unit is formed to constitute an LED lamp lens for a ceiling lamp.

As described above, the LED lamp lens for a ceiling lamp according to the present invention protects the LED light emitting lamp by forming a light emitting lamp receiving groove on the back side of the lens, and it is easy to dissipate heat by attaching the back surface of the LED module to the lamp body chassis, It is a novel invention that has the effect of preventing light leakage or interference by collecting the light sources generated from the LED light emitting lamps so that they do not leak to the outside and spraying them evenly in a limited location.

1 is an exploded view illustrating the configuration of the present invention.
2 is a cross-sectional view showing the configuration of the present invention.
Figure 3 is a cross-sectional view showing a coupled state of the present invention.
4 is a cross-sectional view illustrating another configuration state of the present invention.
5 is a combined cross-sectional view of another configuration state of the present invention.
Figure 6 is a partially cut-away view showing an embodiment of the present invention.
7 is an exemplary view of the use state of the present invention.

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

a lens 40 configured to project the light emitted from the light emitting lamp 31 of the LED module 30 forward without leaking or scattering;

an LED module 30 which is accommodated in the light emitting lamp receiving groove 45 of the lens 40 and constitutes a light emitting lamp 31 emitting light;

The module coupling part 21 for coupling the LED module 30 and the lens coupling part 22 for coupling the lens 40 are formed, and the pressing jaw 25 is the coupling wing 43 of the lens 40 . At the same time as pressing , the lens fixing means is configured so that the contact surface 23 is in close contact with the side surface of the lens 40, and is formed by continuously repeating the left and right to form the installation groove 27 for easy installation on the light fixture 10. and a lamp body chassis 20 to form an LED lamp for a ceiling lamp by integrally combining the lamp body chassis 20, the LED module 30, and the lens 40.

At this time, the lens fixing means is integrally formed with the lamp body chassis 20 to form a bending part 24 and a wedge groove 26, and when the wedge piece 29 is forcibly coupled to the wedge groove 26, the bending part By the bending of (24), the pressing jaw 25 presses the coupling wing 43 of the lens 40, and the contact surface 23 is configured to be in close contact with the side surface of the lens 40.

Here, when the lens fixing means is configured with a separate push bar 50 separated from the lamp body chassis 20 and the head 51 of the push bar 50 is pressed, the push bar 50 is formed on the lamp body chassis 20 ) and the lens 40 slid into the insertion space 28 formed between the side surface 42 and the pressing jaw 55 at the tip presses the coupling wing 43 of the lens 40 to combine the lens 40 It can also be configured so that the back surface of the LED module 30 is in close contact with the lamp body chassis 20 by pressing the LED module 30 at the same time as it is fixed.

The lens 40 is configured to be continuously long from side to side, and the front end surface forms a light transmitting surface 41 of a plane perpendicular to the center line, and both side surfaces 42 are formed in the shape of a front and rear narrow, and a lamp body is formed at the rear end. Coupled to the chassis 20 to form coupling wings 43 for pressing the LED module 30 on both sides, and a light emitting lamp receiving groove 45 into which the light emitting lamp 31 of the LED module 30 is inserted. A convex lens unit 46 is formed in the center of the light emitting lamp receiving groove 45 to constitute an LED lamp lens for a ceiling lamp.

Here, both side surfaces 42 of the lens 40 are formed in the shape of an all-optical constriction at an angle of 60° with one side at an angle of 30°, and the front light-transmitting surface 41 and the rear end have a width of 6 to 12 mm. , the width from the convex surface of the convex lens to the light transmitting surface is 4 to 8 mm, and the radius of the convex lens part 46 is R1.5 spherical.

At this time, the efficiency is the best when the width of the front light transmitting surface 41 and the rear end is 10.1 mm, and the width from the convex surface of the convex lens to the light transmitting surface is 8 mm, and the width of the light transmitting surface 41 and the rear end is 6.1 mm , When the width from the convex surface to the light transmitting surface of the convex lens is 4mm, the lens is compact and convenient to use, but the efficiency tends to be slightly lower.

An exemplary embodiment of the present invention will be described as follows.

The LED module 30 configured in the lamp body chassis 20 by installing the lamp body chassis 20 on the reflective surface 12 and the outer frame 11 with a high center protruding and inclined configuration toward the outer frame 11. ), the light source from which the light emitting lamp 31 is generated is projected on the reflective surface 12 through the lens 40. .

As described above, the present invention used for indirectly irradiated LED ceiling lamps using light reflection has a length suitable for installation on the inner circumferential surface of the outer frame of the luminaire 10 to be installed and used in the lamp body chassis 20 and the lens 40. and the LED module 30 is cut.

When the cutting is completed in this way, the LED module 30 is inserted into the module coupling part 21 of the lamp body chassis 20 and combined.

When the coupling of the LED module 30 is completed in this way, the lens 45 is inserted into the lens coupling part 22 formed in the lamp body chassis 20 and coupled.

At this time, the light emitting lamp 31 of the LED module 30 is inserted into the light emitting lamp receiving groove 45 of the lens 40 and positioned. At this time, the protruding end of the convex lens part 46 of the lens 40 and the LED module 30 Since the space of the rear end of the engaging blade 43 to be in close contact is 2.1 mm, a space is generated.

Therefore, even if the lens 40 causes thermal expansion by the heat source generated from the light emitting lamp 31 during use, no external force acts on the light emitting lamp 31 and thus is protected.

When the lens 45 is inserted and coupled to the lens coupling part 22 formed in the lamp body chassis 20 as described above, the lamp body chassis 20 is in close contact with one side of the lens 40 and the other side is The lamp body chassis 20 maintains the separated state and the LED module 30 is also in a free state.

In this state, when the wedge piece 29 is coupled to the wedge groove 26 of the lamp body chassis 20, which is the lens fixing means, the wedge groove 26 opens and the bending part 24 is bent, so that the pressing jaw 25 Press the coupling blade 43 of the lens 40 toward the LED module 30 to fix the rear surface of the LED module 30 in close contact with the module coupling part 21 of the lamp body chassis 20, and then the lamp body chassis 20 The contact surface 23 of the lens is in close contact with the side surface 42 of the lens 40 to firmly fix the lens.

According to the present invention, which is configured by combining the LED module 30 and the lens 40 as described above, the lamp body chassis 20 is configured to face the outer frame 11 of the lamp 10 or a square outer frame 11 ) to be installed in each.

At this time, when the inclination of the reflective surface 12 of the luminaire 10 is 14° in the horizontal direction, it is ideal that the light transmitting surface 41 of the lens 40 opposite to this has an inclination of 13° in the vertical direction.

Here, as another configuration of the present invention, when the lens constituting means constitutes a separate push bar 50 separated from the lamp body chassis 20 and presses the head 51 of the push bar 50, the push bar 50 Enters from the insertion space 28 formed between the lamp body chassis 20 and the side surface 42 of the lens 40, and the pressing jaw 55 at the tip presses the coupling wing 43 of the lens 40 to the lens ( 40) and at the same time pressing and simultaneously pressing the LED module 30 so that the back surface of the LED module 30 is in close contact with the lamp body chassis 20, the module coupling part of the lamp body chassis 20 ( 21) by inserting and coupling the LED module 30, and then inserting the coupling wing 43 of the lens 40 into the lens coupling part 22 to couple it, and then to the lens fixing means, which is a separate lamp body chassis 20 and separate. of the push bar 50 is inserted into the insertion space 28 formed between the lamp body chassis 20 and the side surface 42 of the lens 40, and the lamp body chassis 20 is attached to the outer frame of the luminaire 10. When coupled to (11), the head 51 of the push bar 50 is pressed in close contact with the outer frame 11 of the luminaire 10, and the push bar 50 is the lamp body chassis 20 and the side of the lens 40. As it slides in the insertion space 28 formed between 42, the pressing jaw 55 at the tip presses the coupling wing 43 of the lens 40 toward the LED module 30 to illuminate the back surface of the LED module 30 as a lamp. It is closely fixed to the module coupling part 21 of the body chassis 20 .

At this time, the reflective surface 12 and the light transmitting surface so that the light source projected through the light transmitting surface 41 of the lens 40 coupled to the lamp body chassis 20 is evenly distributed on the reflecting surface 12 of the luminaire 10 . It is very important to match the angle of (41).

Therefore, as a result of the experiment conducted by the present applicant, when the inclination of the reflective surface 12 of the luminaire 10 is 14° in the horizontal direction, it is most desirable that the light transmitting surface 41 of the lens 40 opposite to this has an inclination of 13° in the vertical direction. It was ideal.

Here, both side surfaces 42 of the lens 40 are enlarged forward so that the light passing through the convex lens unit 46 is not refracted, and has the most ideal 30° inclined surface for guiding the light to be projected onto the light-transmitting surface 41 . The inclination angle of both sides 42 is found in a number of experiments in consideration of the fact that the light source of the LED has straightness.

At this time, the inclination angle has a margin of about 5°, but it is most ideal to have a 30° inclined surface found in the present invention when considering everything and efficiency according to the configuration of the lamp.

And the convex lens part 46 constituting the light emitting lamp receiving groove 45 of the lens 40 is R 1.5, and it is important here that the light emitting lamp 31 of the LED module 30 is installed in the light emitting lamp receiving groove ( 45) and the light emitted from the light emitting lamp 31 cannot be scattered to the outside on the LED module, and even if the lens is thermally deformed, it is configured so as not to have any effect on the light emitting lamp 31.

The present invention, as it is essential to use the LED indirect light as a home ceiling light, it will be said that the industrial use value is great.

10: luminaire 11: outer frame 12: reflective surface
20: lamp body chassis 21: module insertion part 22: lens coupling part
23: adhesive surface 24: bending portion 25: pressing jaw
26: wedge groove 27: installation groove 28: insertion space
29: wedge piece 30: LED module 31: light emitting lamp
40: lens 41: light-transmitting surface 42: side
43: coupling wing 45: light emitting lamp receiving groove 46: convex lens unit
50: press bar 51: head 55: press chin

Claims (5)

a lens 40 configured to project the light emitted from the light emitting lamp 31 of the LED module 30 forward without leaking or scattering;
an LED module 30 which is accommodated in the light emitting lamp receiving groove 45 of the lens 40 and constitutes a light emitting lamp 31 emitting light;
The module coupling part 21 for coupling the LED module 30 and the lens coupling part 22 for coupling the lens 40 are formed, and the pressing jaw 25 is the coupling wing 43 of the lens 40 . The lens fixing means is configured so that the contact surface 23 is in close contact with the side surface 42 of the lens 40 at the same time when pressing LED lamp for a ceiling lamp, characterized in that it is composed of a lamp body chassis (20) that is repeatedly molded, and is formed by integrally combining the lamp body chassis (20), the LED module (30) and the lens (40). According to claim 1,
The lens fixing means is integrally formed with the lamp body chassis 20 to form a bending part 24 and a wedge groove 26, and when the wedge piece 29 is forcibly coupled to the wedge groove 26, the bending part 24 ) for a ceiling lamp, characterized in that the pressing jaw 25 presses the coupling wing 43 of the lens 40 and the contact surface 23 is configured to be in close contact with the side surface 42 of the lens 40 led lamp. According to claim 1,
The lens fixing means constitutes a separate push bar 50 separated from the lamp body chassis 20 so that when the head 51 of the push bar 50 is pressed, the push bar 50 becomes the lamp body chassis 20 . Entering from the insertion space 28 formed between the side surface 42 of the lens 40 and the pressing jaw 55 at the tip presses the coupling wing 43 of the lens 40 to fix the lens 40 and LED lamp for ceiling lamp, characterized in that by pressing the LED module (30) at the same time as pressing at the same time to configure the back surface of the LED module (30) to be in close contact with the lamp body chassis (20). In configuring the lens 40 to be continuously long from side to side,
The front end surface forms a flat light transmitting surface 41 that is perpendicular to the center line, and both side surfaces 42 are formed in the shape of an all-light and rear narrow shape. The main coupling wings 43 are formed on both sides, and the light emitting lamp receiving groove 45 in which the light emitting lamp 31 of the LED module 30 is accommodated is formed inside the light emitting lamp receiving groove 45, and a convex lens is formed in the center. LED lamp lens for a ceiling lamp, characterized in that forming a portion (46). 3. The method of claim 2,
Both side surfaces 42 of the lens 40 are formed in the shape of a front and rear constriction at an angle of 60° with one side at an angle of 30°, and the front light-transmitting surface 41 and the rear end have a width of 6-12 mm, LED lamp lens for a ceiling lamp, characterized in that the width from the convex surface of the convex lens to the light transmitting surface is 4 to 8 mm, and the radius of the convex lens part 46 is R1.5.

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