KR102297209B1 - LED lighting device with excellent pollution prevention function - Google Patents

Abstract

The present invention relates to an LED lighting device installed outdoors or on a road. According to the present invention, the LED lighting device comprises: a lighting body (10) installed on the upper end of a post built outdoors or on a road; an LED module (20) embedded in the lower end of one side of the lighting body (10) and emitting light downward; a transparent light-transmitting cover (30) mounted on the lower end of one side of the lighting body (10) to seal the LED module (20); and a coating layer (40) coated on the lighting body (10) or the light-transmitting cover (30) to dissipate contaminants attached to the outer surface by a photolysis action caused by natural light. Accordingly, since a coating agent performing a photolysis action is coated on a lighting body or a light-transmitting cover, various contaminants adhering to the outer surface of the lighting body or transparent cover are automatically decomposed, thereby providing an effect of significantly increasing lifespan of the lighting device. In addition, cleanliness of the light-transmitting cover is maintained at all times, thereby providing an effect of saving energy with excellent light efficiency.

Description

LED lighting device with excellent pollution prevention function

The present invention relates to an LED lighting device that maximizes the pollution prevention function installed on the edge of the road or outdoors, such as a road or park, and more particularly, a special coating agent that has a photolytic action on a lighting body or a light-transmitting cover (lens) is coated In addition, UV-A LED (ultraviolet lamp) to maximize photolysis is separately attached to photodecompose various contaminants (organic compounds) attached to the lower part of the lighting body or transparent cover (lens) and illuminate as it extinguishes the sterilization process. Pollution prevention function that not only can significantly increase the life of the instrument, but also save energy by maintaining excellent light efficiency by maintaining the cleanliness of the transparent cover (lens) at all times, and reduce air pollution by decomposing environmental pollutants It is about an LED lighting fixture that maximizes the

In general, LED lighting fixtures installed outdoors contaminate the lens part of LED lighting fixtures due to organic substances such as spider webs and bird droppings and pollutants such as sulfur oxides (SOx) and nitrogen oxides (NOx) emitted from vehicles for light efficiency. There is a problem of rapidly lowering the

In addition, the LED lighting equipment has a problem of shortening the overall lifespan of the LED lighting equipment because the oxidation rate is rapidly increased due to uric acid and the like as the lighting body is mostly made of aluminum for heat dissipation.

In recent years, as a way to solve this problem, in addition to the simple light irradiation function, not only the improvement of mechanical strength, mechanical properties, electrical properties and light efficiency, but also the development of technologies for adding negative ions, far-infrared radiation, photocatalysts, etc. are being actively developed. .

That is, photocatalytic and antibacterial functions are added by coating a photocatalytic reaction paint containing anatase-type titanium dioxide on the body or lens of a lighting device.

However, since the infrared rays received from sunlight in a general living space are about 3mW/cm2, organic compounds in ppm unit can be decomposed to some extent, but it takes a lot of time to decompose organic compounds such as spider silk in g units deposited on LED lighting fixtures. .

For example, it takes 12 hours to decompose 168 g (1 mol) of tetrachloroethane with titanium dioxide with UV intensity of 3 mW/cm 2 and quantum efficiency of 100%. There is a problem that prevents it from performing properly.

Republic of Korea Patent Publication No. 10-1296285 (Title of the invention: Eco-friendly powder paint and lighting fixture using the same)

The present invention has been proposed to solve the above problems, and by coating a light-decomposing coating agent on the lighting body or the light-transmitting cover, it automatically extinguishes various contaminants attached to the outer surface of the lighting body or the light-transmitting cover. The purpose of this is to provide an LED lighting fixture that maximizes the pollution prevention function that can significantly increase the lifespan of the light-transmitting cover and save energy with excellent light efficiency by maintaining the cleanliness of the transparent cover at all times.

In addition, the present invention is a transparent cover that does not reach natural light by separately attaching a UV-A LED having a wavelength of 360 to 380 nm that does not affect the human body on the lower outer surface of the lighting body or the transparent cover (lens) in order to maximize photolysis By automatically extinguishing various pollutants and environmental pollutants such as sterilization treatment, the lifespan of lighting equipment can be greatly increased, and excellent light efficiency can be maintained by maintaining the cleanliness of the transparent cover (lens) at all times, saving energy. The purpose of this is to provide an LED lighting fixture that can save money and maximize the pollution prevention function to purify environmental pollutants.

The present invention relates to an LED lighting device installed on a road or a park, comprising: a lighting body installed on the top of a post built outdoors or on a road; an LED module embedded in a lower end of one side of the lighting body and irradiating light downward; a transparent light-transmitting cover (lens) mounted on one side of the lower end of the lighting body to seal the LED module; A coating layer that is coated on the lighting body or the light-transmitting cover (lens) to dissipate the contaminants attached to the outer surface due to the photolysis action caused by natural light; characterized in that it comprises a UV-A LED for maximizing photolysis.

At this time, the coating layer according to the present invention is ^{coated with a coating agent composed of titanium dioxide (TiO 2} ) on the lighting body or the light-transmitting cover (lens), and then fired at 90 to 110° C. for 30 to 90 minutes.

In addition, the coating agent according to the present invention is a mixture of anatase titanium dioxide, which photolysis occurs in a light wavelength band of 380 nm or less, rutile titanium dioxide, which photolysis occurs in a light wavelength band of 415 nm, and brookist titanium dioxide, which photodecomposes in a light wavelength band of 520 nm. characterized in that

In addition, the coating agent according to the present invention is characterized in that 40-60 wt% of anatase titanium dioxide, 20-40 wt% of rutile titanium dioxide, and 10-30 wt% of brookist titanium dioxide are mixed.

In addition, the lighting body according to the present invention, a circular or prismatic aluminum housing mounted on the upper end of the support; a cover frame mounted on the lower end of one side of the housing to press and fix the light-transmitting cover (lens); a control module built in the lower end of the other side of the housing to supply power to the LED module; a control cover mounted on the lower end of the other side of the housing to protect the control module to be sealed; airtight packing interposed between the housing, the light-transmitting cover (lens) and the control cover to block the seam; a cable gland mounted on the upper end of the other side of the housing and passing through an externally connected wire in a sealed state; It characterized in that it is composed of; a connection member mounted on the other side of the housing to induce removal/installation from the pole.

In addition, the housing according to the present invention, an LED groove recessed to a predetermined shape and depth at the lower end of one side so that the LED module is embedded; a control groove recessed to a predetermined shape and depth at the lower end of the other side so that the control module is embedded; a heat sink protrudingly arranged in a predetermined pattern on the upper end to receive heat from the LED module and radiate it to the outside; an airtight piece protruding at a predetermined height from the bottom edge side to improve airtightness by engaging the cover frame and the control cover in multiple stages; A plurality of screw grooves recessed to a predetermined depth on the bottom edge side so that the cover frame and the control cover are fastened with screws; characterized in that it is formed.

In addition, the connection member according to the present invention is mounted on the upper end of the other side of the housing, and an Ω-type clamp for accommodating a pipe horizontally disposed on the upper end of the post; characterized in that it is composed of.

In addition, the connection member according to the present invention, a plurality of fixing bolts that are through-fastened to the lower end of the other side of the housing and press and fix the pipe accommodated in the clamp; characterized in that it is further configured.

In addition, the LED lighting device according to the present invention is mounted on the lower end of the other side of the lighting body, and irradiates UV-A LED in the 360-380 nm optical wavelength band toward the transparent cover (lens) to double the photolysis action; It is characterized in that it further comprises.

In addition, the control cover according to the present invention, a fixed frame protruding to a predetermined height at the bottom so that the UV-A LED is mounted; A connection hole having a predetermined size is formed in the center so that the control module and the UV-A LED are connected with an electric wire.

First, in the present invention, by coating a light-decomposing coating agent on the lighting body or the light-transmitting cover (lens), various contaminants attached to the outer surface of the lighting body or the light-transmitting cover (lens) are automatically extinguished, thereby prolonging the life of the lighting equipment. Not only can it increase significantly, but it also has the effect of saving energy with excellent light efficiency by maintaining the cleanliness of the transparent cover (lens) at all times.

Second, the present invention constitutes a UV-A LED that maximizes the photodegradation action by irradiating ultraviolet rays toward the light-transmitting cover (lens). It has the effect of annihilating organic compounds such as spider silk, which are impossible.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a configuration diagram showing the overall lighting device according to the present invention.
2 is an exploded view showing a lighting device according to the present invention by separating it.
3 and 4 are detailed views independently showing the lighting body of the lighting device according to the present invention.
5 is a configuration diagram showing the overall lighting device according to a modification of the present invention.
6 is an exploded view showing the lighting device according to FIG. 5 separated.
7 is an operational state diagram illustrating a state in which the lighting device according to FIG. 5 according to the present invention causes photolysis by irradiating ultraviolet rays.

Hereinafter, various embodiments of the present document will be described with reference to the accompanying drawings. However, this is not intended to limit the technology described in this document to specific embodiments, and it should be understood that the present document includes various modifications, equivalents, and/or alternatives of the embodiments of this document. In connection with the description of the drawings, like reference numerals may be used for like components.

In addition, expressions such as "first," "second," used in this document may modify various elements regardless of order and/or importance, and to distinguish one element from another element. It is used only and does not limit the corresponding components. For example, 'first part' and 'second part' may represent different parts regardless of order or importance. For example, without departing from the scope of the rights described in this document, the first component may be named as the second component, and similarly, the second component may also be renamed as the first component.

In addition, terms used in this document are used only to describe specific embodiments, and may not be intended to limit the scope of other embodiments. The singular expression may include the plural expression unless the context clearly dictates otherwise. Terms used herein, including technical or scientific terms, may have the same meanings as commonly understood by one of ordinary skill in the art described in this document. Among the terms used in this document, terms defined in a general dictionary may be interpreted with the same or similar meaning as the meaning in the context of the related art, and unless explicitly defined in this document, ideal or excessively formal meanings is not interpreted as In some cases, even terms defined in this document cannot be construed to exclude embodiments of the present document.

The present invention relates to an LED lighting device installed outdoors or at the edge of a road, such as a park or a garden, and includes a lighting body 10, an LED module 20, and a light-transmitting bucket 30 and a coating layer 40 as shown in FIG. It is an LED lighting fixture with an excellent anti-pollution function.

First, the lighting body 10 according to the present invention is a body for accommodating the LED module 20 and the light-transmitting bucket 30 as shown in FIG. 1 , and is installed at the top of a post built outdoors or on a road.

As shown in FIG. 2, the lighting body 10 includes a housing 11, a cover frame 12, a control module 13, a control cover 14, an airtight packing 15, a cable gland 16, Consists of a connecting member (17).

The housing 11 is an aluminum case mounted on the top of the post, and is formed in a circular or square shape.

An LED groove 11a is formed in the lower right side of the housing 11, which is recessed to a predetermined shape and depth as shown in FIGS. 3 and 4 to accommodate the LED module 20. As shown in FIGS.

In addition, a control groove 11b is formed at the lower left end of the housing 11 to have a predetermined shape and depth to accommodate the control module 13 .

Here, the LED groove 11a and the control groove 11b are formed to be isolated from each other, and a through hole is formed in the center so that the control module 13 and the LED module 20 are interconnected by wires.

In addition, a heat sink 11c is formed on the upper end of the housing 11 to protrude in a predetermined pattern to receive heat from the LED module 20 and radiate it to the outside.

In addition, an airtight piece 11d protruding to a predetermined height is formed on the edge of the LED groove 11a and the control groove 11b of the bottom surface of the housing 11 .

The airtight piece 11d is a light-transmitting cover (lens) 13 that seals the LED groove 11a and the control groove 11b, the cover frame 12 and the control cover 14 are engaged in multiple stages to improve airtightness. give.

In addition, a plurality of screw grooves 11e recessed to a predetermined depth are formed on the inner edges of the LED grooves 11a and the control grooves 11b among the bottom surfaces of the housing 11 .

That is, the screw groove (11e) induces a firm and close mounting by allowing the cover frame 12 and the control cover 14 to be fastened with bolts or screws.

Then, the cover frame 12 is mounted in engagement with the airtight piece 11d provided in the LED groove 11a, and is fixed by pressing the light-transmitting cover (lens) 13 .

The cover frame 12 is formed in a circular and rectangular frame according to the shape of the LED groove 11a, and a plurality of holes are formed so as to be fastened to the screw groove 11e through a screw.

The control module 13 is built into the control groove 11b of the housing 11 to supply power to the LED module 20 and the UV-A LED 50 to be described later.

The control module 13 includes an adapter that receives and converts external power, an LED driver that supplies power to the LED module 20, and a controller that regulates power.

The control cover 14 is mounted in engagement with the airtight piece 11d provided in the control groove 11b to protect the control module 13 to be hermetically sealed.

The airtight packing 15 is made of a soft resin material and is interposed between the housing 11, the light-transmitting cover (lens) 30 and the control cover 14, respectively, to block the seam.

The cable gland 16 is mounted to be exposed to the outside from the control groove 11b and passes the electric wire connected to the outside in a sealed state.

The connecting member 17 is mounted on the left side of the housing 11 to induce detachment/attachment from the post.

This connection member 17 is mounted on the upper left side of the housing 11 is composed of an Ω-type clamp (17a) for accommodating a pipe arranged horizontally on the upper end of the post.

Here, it is preferable to form a semicircular groove portion for accommodating the pipe of the post on the upper left side of the housing 11 in which the clamp 17a is mounted.

At this time, the connecting member 17 may further comprise a fixing bolt 17b that is penetrated and fastened to the lower left end of the housing 11 to press and fix the pipe accommodated in the clamp 17a.

That is, it is installed by inserting and mounting the pipe of the post into the clamp (17a) and then tightening the fixing bolt (17b) to press it.

Therefore, it is possible to omit the process of removing/attaching the clamp 17a and the fixing bolt 17b from the housing 11, as well as fast and simple installation only by tightening or loosening the fixing bolt 17b, thereby reducing the man-hours. can

And the LED module 20 according to the present invention is built in the lower right of the lighting body 10 as shown in FIGS. 1 and 2 to irradiate light downward.

That is, the LED module 20 is composed of an LED substrate connected to the control module 13 and an electric wire, and LEDs arranged in a predetermined pattern on the LED substrate.

This LED module 20 is mounted with screws or bolts in a state in close contact with the LED groove 11a.

Here, it is preferable to interpose a thermal pad having a thermal conductivity of 12W/mk or more between the LED module 20 and the lighting body 10 so that the heat generated from the LED is rapidly discharged.

Next, the light-transmitting cover (lens) 30 according to the present invention is mounted on the lower right side of the lighting body 10 as shown in FIGS. 1 and 2 to seal the LED module 20 .

That is, the light-transmitting cover (lens) 30 is mounted in engagement with the airtight piece 11d provided in the LED groove 11a to protect the control module 13 to be hermetically sealed.

The light-transmitting cover (lens) 30 is a lens that diffuses and transmits the light irradiated from the LED module 20, and is formed of transparent glass or a resin material.

Here, the light-transmitting cover (lens) 30 may be formed in a flat, spherical, or aspherical shape according to an installation environment or a user's request, and may also be formed in a semi-transparent shape having a set color.

Finally, the coating layer 40 according to the present invention extinguishes the contaminants attached to the outer surface due to the photolysis action caused by natural light.

The coating layer 40 may be coated on the lighting body 10 or the light-transmitting cover (lens) 30 , or may be coated on both the lighting body 10 and the light-transmitting cover (lens) 30 .

^{That is, the coating layer 40 is coated with a coating agent composed of titanium dioxide (TiO 2} ) on the outer surface of the lighting body 10 or the light-transmitting cover (lens) 30 and then baked at 90 to 110° C. for 30 to 90 minutes. do.

The titanium dioxide coating layer 40 converts water and carbon dioxide into methane, carbon monoxide, and a large amount of oxygen through a photocatalytic reaction to remove contaminants and exhibit deodorization and sterilization properties.

Here, the coating agent is a mixed composition of anatase titanium dioxide 40-60 wt%, rutile titanium dioxide 20-40 wt%, and brookist titanium dioxide 10-30 wt%.

That is, anatase titanium dioxide is photodegraded in a light wavelength band of 380 nm or less, rutile titanium dioxide is photodegraded in a light wavelength band of 415 nm and brookist titanium dioxide is 520 nm.

This anatase, rutile, and brookist mixed titanium dioxide is photodegraded not only in ultraviolet rays but also in the visible wavelength band of 500 nm, so it exhibits an excellent function of removing pollutants indoors as well as outdoor environments with insufficient sunlight.

Therefore, it is preferable to mix the composition with 50% by weight of amorphous anatase titanium dioxide, 30% by weight of crystalline rutile titanium dioxide, and 20% by weight of brookist titanium dioxide.

On the other hand, since the light-transmitting cover (lens) 30, which is the most important for light efficiency, is located at the bottom of the lighting device, there are many shade areas even during the daytime when the sun rises, so the photolysis action is insufficient.

Of course, it is possible to absorb the visible light irradiated from the LED module 20 to exert a photolysis action.

However, since the LED module 20 irradiates light from the evening at sunset to the morning at sunrise, the photolysis action is quite insufficient.

That is, even though the coating layer 40 in which photodecomposition occurs in the ultraviolet and visible wavelength bands is formed, the light-decomposing action of the light-transmitting cover (lens) 30 is insufficient, so supplementation is required.

Therefore, the lighting device of the present invention can further constitute a UV-A LED 50 for irradiating ultraviolet rays by being mounted on the lower left side of the lighting body 10 as shown in FIGS. 5 and 6 .

Here, the control cover 14 has a fixed frame 14a protruding to a predetermined height at the lower end so that the UV-A LED 50 is mounted.

In addition, a connection hole 14b through a predetermined size is formed in the center so that the control module 13 and the UV-A LED 50 are connected with an electric wire.

The UV-A LED 50 irradiates ultraviolet rays in a wavelength band of 315 to 400 nm toward the light-transmitting cover (lens) 30 as shown in FIG. 7 to compensate for the insufficient photolysis.

That is, the UV-A LED 50 compensates for the insufficient photolysis action of the light-transmitting cover (lens) 30, thereby rapidly dissipating various contaminants, thereby increasing the lifespan of the light-transmitting cover (lens) 30. have.

Above all, through strong photolysis by the UV-A LED 50, organic compounds such as spider silk, which cannot be decomposed with natural light alone, can be extinguished, thereby remarkably increasing the light efficiency of the overall lighting equipment.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications may be made by those having the knowledge of, of course, and these modified embodiments should not be individually understood from the technical spirit or perspective of the present invention.

10: light body
11: housing
11a: LED Home
11b: control home
11c: heat sink
11d: Confidential
11e: screw groove
12: cover frame
13: control module
14: control cover
14a: fixed frame
14b: connection hole
15: airtight packing
16: cable gland
17: connecting member
17a: clamp
17b: fixing bolt
20: LED module
30: transparent cover
40: coating layer
50: UV-A LED (ultraviolet lamp)

Claims (8)

In the LED lighting equipment installed outdoors or on the road,
Lighting body (10) installed on the top of the post built outdoors or on the road;
an LED module 20 embedded in a lower end of one side of the lighting body 10 and irradiating light downward;
a transparent light-transmitting cover (lens) 30 mounted on the lower end of one side of the lighting body 10 to seal the LED module 20;
A coating layer 40 coated on the lighting body 10 or the light-transmitting cover (lens) 30 to dissipate the contaminants attached to the outer surface by the photolysis action caused by natural light;
The coating layer 40,
The lighting body 10 or the light-transmitting cover (lens) 30 ^{is coated with a coating agent composed of titanium dioxide (TiO 2} ) and then fired at 90 to 110° C. for 30 to 90 minutes,
The coating agent is a mixture of anatase titanium dioxide, which photodecomposes in the optical wavelength band of 380 nm or less, rutile titanium dioxide, in which photodecomposition occurs in the 415 nm optical wavelength band, and brookist titanium dioxide, in which photodecomposition occurs in the optical wavelength band of 520 nm.
The lighting body 10,
a circular or prismatic aluminum housing 11 mounted on the top of the post;
a cover frame 12 mounted on a lower end of one side of the housing 11 to press and fix the light-transmitting cover (lens) 30;
a control module (13) built in the lower end of the other side of the housing (11) to supply power to the LED module (20);
a control cover 14 mounted on the lower end of the other side of the housing 11 to protect the control module 13 to be hermetically sealed;
airtight packing 15 interposed between the housing 11 and the light-transmitting cover (lens) 30 and the control cover 14 to block the seam;
a cable gland 16 mounted on the upper end of the other side of the housing 11 to pass an externally connected electric wire in a sealed state;
It is mounted on the other side of the housing (11) and a connection member (17) for inducing removal/installation from the pole;
The LED lighting device is
A UV-A LED (50) mounted on the lower end of the other side of the illumination body (10) and irradiating ultraviolet rays in a wavelength band of 315 to 400 nm toward the light-transmitting cover (lens) 30 to double the photolysis action;
The connecting member 17,
A plurality of fixing bolts (17b) that are through-fastened to the lower end of the other side of the housing (11) and press and fix the pipe accommodated in the clamp (17a);
The control cover 14,
a fixing frame 14a protruding to a predetermined height at the bottom so that the ultraviolet lamp 50 is mounted;
a connection hole (14b) having a predetermined size in the center so that the control module (13) and the ultraviolet lamp (50) are connected with an electric wire;
An LED lighting fixture that maximizes the anti-pollution function, characterized in that this is formed. delete delete The method according to claim 1,
The coating agent is anatase titanium dioxide 40-60% by weight, rutile titanium dioxide 20-40% by weight, and brookist titanium dioxide 10-30% by weight LED lighting equipment that maximizes the anti-pollution function, characterized in that the composition is mixed. delete The method according to claim 1,
The housing 11 is
an LED groove 11a recessed to a predetermined shape and depth at the lower end of one side so that the LED module 20 is embedded;
a control groove (11b) recessed to a predetermined shape and depth at the lower end of the other side so that the control module (13) is embedded;
a heat sink (11c) protruding in a predetermined pattern on the upper end to receive heat from the LED module (20) and radiate to the outside;
Airtight pieces (11d) protruding at a predetermined height from the bottom edge side to improve airtightness by engaging the cover frame (12) and the control cover (14) in multiple stages;
a plurality of screw grooves 11e recessed to a predetermined depth on the bottom edge side so that the cover frame 12 and the control cover 14 are fastened with screws;
An LED lighting fixture that maximizes the anti-pollution function, characterized in that this is formed. The method according to claim 1,
The connecting member 17,
an Ω-shaped clamp (17a) mounted on the upper end of the other side of the housing (11) and accommodating a pipe horizontally disposed on the upper end of the post;
An LED lighting fixture that maximizes the pollution prevention function, characterized in that it is composed of delete

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