KR20200002334U - Lighting led reclamation lamp with waterproof structure - Google Patents

Abstract

A transparent plate that transmits illumination light by the LED lamp 300 housed in the buried body 200 constituting the buried lamp is adopted as an acrylic material, and the outer circumferential surface thereof and the upper and lower surfaces extending from the outer circumferential surface are enclosed. A waterproof structure that guarantees economical efficiency and reliability by providing airtightness while excluding a separate rubber ring material while the lower flange bent part 210 and the protrusion 240 processed on the upper bent part 220 are compressed in the assembly groove part 230 It is in providing LED reclamation.
The object of the present invention is to form an expanded flange bent part 210 in the open part in the shape of an enclosure by pressing a buried body made of aluminum material, and the upper part extending from the flange bent part 210 by seating a transparent plate thereon. In the embedding, etc. assembled in a state where the bent part 220 is bent and the outer circumferential surface and the upper and lower surfaces of the transparent plate are wrapped with an assembly groove 230,
The transparent plate is provided with an acrylic transparent plate 100, a protrusion 240 is formed on the flange bent part 210, and the outer circumferential surface of the acrylic transparent plate 100 is extended and bent at the flange bent part 210 And the assembly groove 230 formed by bending the upper bent part 220 surrounding a part of the upper surface connected from the outer circumferential surface is pressed, and the protrusion 240 is compressed to the lower surface of the acrylic transparent plate 100 to be airtight. It can be achieved by embedding the waterproof structure LED.

Description

Waterproof structure LED reclamation lamp {LIGHTING LED RECLAMATION LAMP WITH WATERPROOF STRUCTURE}

The present invention relates to an embedding lamp that is embedded and installed in the ceiling of a space where moisture is generated constantly, such as a bathroom, and more specifically, the perfect airtightness of the interface of the assembly part of the body and the acrylic floodlight plate bonded to the body embedded in the ceiling. It relates to a moisture-proof structure that provides a moisture-proof structure that blocks moisture from penetrating the body through a moisture-proof structure that is suitable for LED lighting and guarantees the reliability of the embedded light product with a guarantee of life.

LED (Light Emitting Diode), which has been in the spotlight in recent years, is compact and has a longer lifespan compared to conventional light sources, and it consumes less power because it directly converts electrical energy into light energy and emits high brightness with excellent energy efficiency. There is an advantage.

These LEDs are guaranteed to have life in places where natural air contacts such as indoor lights and decorations, but when used in places where moisture is constantly generated, such as toilets or bathrooms, it is not necessary to block moisture contact with the LED provided inside. need.

Therefore, the moisture barrier structure such as buried is assembled through a number of fastening members (screws or bolts and nuts) with a separate rubber ring interposed at the interface between the floodlight and the embedded body that couples it, but this is the airtightness of the floodlight. There is a disadvantage in that the work process according to the assembly is complicated and the manufacturing cost increases due to the need for a separate rubber ring material.

Thus, as in Patent Document 1, the present applicant has registered a prefabricated embedding, etc., which assembles a circular glass plate of a light-transmitting plate as a simple structure by binding a circular glass plate, which is a light-transmitting plate, to a body such as a buried light by simple bending. .

Looking at such an applicant's source technology with reference to Figures 1a to 1c schematically shown,

An upper bent part 22 extending from the flange bent part 21 in a state in which a flange bent part 21 having a stepped structure is formed in front of the buried body 20 and a circular glass plate 10, which is a transparent plate, is seated thereon. It is assembled by wrapping the upper and lower surfaces around the outer circumferential surface of the circular glass plate 10 in a state in which the assembly groove 23 is formed by the bending process.

However, this source technology has the advantage of reducing the manufacturing cost by binding the buried body 20 forming a buried, etc. and the circular glass plate 10 which is a transparent plate by not adopting a sealing material as in the prior art for internal airtightness. Since the outer circumferential surface of the circular glass plate 10 is combined with the upper bent part 22 bent in the buried body 20 by bending and compression processing that does not damage the glass plate, it is not possible to obtain the compressive strength in consideration of the damage of the glass plate. By assembling the circular glass plate 10 to the extent that it is supported by the assembly groove 23 formed by bending, the bent portions 21 and 22 of the buried body 20 and the glass plate 10 are placed in a place where there is always a lot of humidity. Moisture easily penetrates through the gap formed between the interfaces of the device, and as a result, moisture penetrates into the lamp for internal lighting, thereby shortening the lifespan due to a short circuit.

Korean Registered Office No. 20-0453021 (registered on March 25, 2011)

The problem to be solved by the present invention is to adopt a floodlight plate that transmits the illumination light by the LED lamp housed inside the body constituting the buried lamp as an acrylic material, and wraps the outer circumferential surface thereof and the upper and lower surfaces extending from the outer circumferential surface. It is to provide a waterproof structure LED embedding that guarantees economical efficiency and reliability by providing airtightness in a state where a separate rubber ring material is excluded while the lower flange bent portion and the upper bent portion are compressed.

The waterproof structure LED embedding of the present invention to achieve the above object,

The body made of aluminum is pressed into the shape of the enclosure to form an extended flange bent in the open part, and the light-transmitting plate is seated and the upper bent part extended from the flange bent is bent to form the outer circumferential and upper and lower surfaces of the transparent plate. In the embedding, etc. assembled while wrapping

The light-transmitting plate is provided with an acrylic light-transmitting plate, forming a protrusion on the flange bent portion and extending and bent from the flange bent portion to cover the outer circumferential surface of the light-transmitting plate and a portion of the upper surface connected from the outer circumferential surface is bent by bending While being pressed, the protrusion is pressed against the lower surface of the transparent plate to be airtight.

Here, a protrusion may also be formed in the upper bent portion, bent and compressed, and the protrusion may be compressed on the upper and lower surfaces of the transparent plate to provide airtightness.

According to the present invention, the unique airtight structure is possible by simple processing in the use by improving the applicant's seafarer technology and embedding it in the ceiling of the bathroom where moisture is constantly generated. Industrially, a mass production effect can be expected, and it becomes possible to provide it at low cost.

In addition, according to the present invention, the heat generated by the LED provided inside the body can be cooled with a radiating fin protruding from the outside, thereby ensuring a service life.

1A to 1B are cross-sectional views showing the structure of an applicant's crew, such as a prefabricated burial,
1A is a diagram illustrating a state in which a circular glass plate is seated on an embedded body such as burial,
1B is a state diagram in which a circular glass plate is bound and assembled to a buried body,
1C is an enlarged view of an excerpt of “A” part of FIG. 1B.
2A to 2D are cross-sectional views showing a structure in which a protrusion is protruded at the beginning of a flange bent portion as a preferred embodiment of the present invention,
2A is a diagram illustrating a state in which an acrylic transparent plate is seated on a buried body such as a buried, etc.,
Figure 2b is an enlarged view of an excerpt of "B" part of Figure 2a,
2C is a state diagram in which an acrylic transparent plate is bound and assembled to a buried body,
FIG. 2D is an enlarged view of part “C” of FIG. 2C.
3A to 3D are cross-sectional views illustrating a structure in which a protrusion is protruded in an intermediate portion of a flange bent portion as another embodiment of the present invention,
3A is a diagram illustrating a state in which an acrylic transparent plate is seated on a buried body such as a buried, etc.,
3B is an enlarged view of an excerpt of “D” part of FIG. 3A,
3C is a state diagram in which an acrylic transparent plate is bound and assembled to a buried body,
3D is an enlarged view of an excerpted portion "E" of FIG. 3C.
4A to 4D are cross-sectional views showing a structure in which each protrusion is protruded in an intermediate portion of a flange bent portion and an upper bent portion as another embodiment of the present invention,
4A is a diagram illustrating a state in which an acrylic transparent plate is seated on a buried body of a buried, etc.,
Figure 4b is an enlarged view of the "F" part of Figure 4a,
4C is a state diagram in which an acrylic transparent plate is bound and assembled to a buried body,
4D is an enlarged view of an excerpt of “G” in FIG. 4C.
5a to 5b are another embodiment of the present invention,
5A is a cross-sectional view of a radiating fin configured to air-cool the heat generated by an LED, which is an internal light source of a buried body, through heat exchange with external air,
5B is an enlarged view of an excerpt of “H” in FIG. 5A.

Hereinafter, a detailed look at the configuration of the present invention with reference to the accompanying drawings are as follows.

As shown in Figs. 2a to 2b presented as a preferred embodiment of the present invention, the waterproof LED buried lamp of the present invention combines the acrylic transparent plate 100 as a transparent plate and the acrylic transparent plate in an airtight state at the open part It is divided into a buried body 200 made of an aluminum material, and an LED lamp 300 cooked with screws or the like inside the buried body.

It is preferable that the acrylic transparent plate 100, which is a transparent plate, has a semi-transparent material or a surface for imparting a diffuse reflection function to be formed in a fine uneven structure in order to prevent visual glare.

The acrylic transparent plate 100 is more preferably a material having a ductility pressed against compression, but may be a hard material capable of being deformed by pressing against an external pressure.

The aluminum buried body 200 forms an expanded flange bent part 210 in the open part as an enclosure container shape by pressing the aluminum plate, that is, drawing, and the acrylic transparent plate 100 is mounted thereon. By bending the upper bent part 220 extended from the flange bent part 210 and being formed inside the assembly groove 230, the outer circumferential surface of the light-transmitting plate 100 and the surrounding upper and lower surfaces are wrapped. Assemble.

At this time, in the state in which the protrusion 240 is formed on the flange bent part 210, it is extended and bent at the flange bent part 210 to cover the outer circumferential surface of the transparent plate 100 and a part of the upper surface connected from the outer circumferential surface. As the part 220 is bent and pressed by bending, the protrusion 240 is compressed to the lower surface of the transparent plate 100 to be airtight.

It is preferable that the protrusion 240 is formed at the bending start end of the flange bent portion 210.

By bending the upper bent part 220, the assembly groove part 230 is narrowly formed by the protrusion 230 at the entrance side, and the lower surface of the acrylic transparent plate 210 is compressed in a state that It is tightly airtight without an airtight ring (rubber ring) of, and moisture penetration through the interface between the upper bent portion 220 and the flange bent portion 210 surrounding the transparent plate 100 is blocked.

3A to 3D are different embodiments of the present invention in that the protrusion 240 presented in the preferred embodiment of the present invention is processed in the middle of the flange bent part 210.

In this embodiment, too, by bending the upper bent part 220, the assembly groove part 230 is compressed by pressing the lower surface of the acrylic transparent plate 210 in a state formed narrowly by a protrusion 240 at the middle side. By being bound in a state, it is tightly airtight without a separate sealing ring (rubber ring), and moisture penetration through the interface between the upper bent portion 220 surrounding the transparent plate 100 and the flange bent portion 210 is blocked.

4A to 4D are different embodiments of the present invention in that the protrusions 240 and 250 are protruded in the middle portion of the flange bent part 210 and the upper bent part 220.

In this embodiment, too, the assembly groove 230 by the bending of the upper bent part 220 is the protrusion 240 of the flange bent part 210 and the protrusion 250 of the upper bent part 220 at the middle side. The upper and lower portions of the acrylic light-transmitting plate 210 are tightly sealed without a separate air-tight ring (rubber ring) as the upper and lower surfaces of the acrylic light-transmitting plate 210 are compressed in a state that is formed narrowly by Moisture penetration through the interface between the upper bent portion 220 and the flange bent portion 210 is blocked.

As shown in Figures 5a to 5b, the present invention installs a heat dissipation fin 400 on the outside of the bottom of the buried body 200 to dissipate heat generated from the LED lamp 300 accommodated therein by heat exchange. Can provide.

The heat dissipation fin 400 is a well-known technology, and it will be sufficiently understood even if a detailed description thereof is omitted.

The present invention connects power to the LED lamp 300 assembled therein while engaging the flange bent part 210 of the buried body 200 in the buried hole processed in the ceiling of the bathroom, 110) to perform indoor lighting.

The present invention has the advantage of ensuring a lifespan by blocking moisture penetration into the LED lamp 300 installed inside the buried body 200 even when used in a bathroom where moisture is constantly generated, such as a bathroom.

100: acrylic floodlight 200: buried body
210: flange bent portion 220: upper bent portion
230: assembly groove 240,250: protrusion
300: LED lamp 400: radiating fin

Claims (3)

By pressing a buried body made of aluminum material, a flange bent part 210 that is extended in the open part is formed in the shape of a case, and a transparent plate is seated thereto, and the upper bent part 220 extended from the flange bent part 210 is formed. In the embedding, etc. assembled in a state where the outer circumferential surface and the upper and lower surfaces of the transparent plate are bent and wrapped with an assembly groove 230
The transparent plate is provided with an acrylic transparent plate 100, a protrusion 240 is formed on the flange bent part 210, and the outer circumferential surface of the acrylic transparent plate 100 is extended and bent at the flange bent part 210 And the assembly groove 230 formed by bending the upper bent part 220 surrounding a part of the upper surface connected from the outer circumferential surface is pressed, and the protrusion 240 is compressed to the lower surface of the acrylic transparent plate 100 to be airtight. Waterproof structure LED landfill, characterized in that.
The method of claim 1,
The protrusion 240 of the flange bent part 210 is molded at the bent start end or the center of the flange bent part 210.
The method of claim 1,
Each of the protrusions 240 and 250 is compressed and airtight on the upper and lower surfaces of the acrylic transparent plate 100 while being bent and compressed by processing a protrusion 250 on the upper bent part 220. Waterproof structure LED reclamation.

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