KR20110113909A - Ceiling mounted LED downlight luminaire structure - Google Patents

Abstract

The present invention relates to a ceiling-mounted downlight luminaire structure, which includes a heat sink having a heat dissipation structure, an LED module consisting of a printed circuit board and LEDs, a heat sink for attaching an LED module, an illumination cylinder, a cap, a cover lens, and a leaf spring. It is composed.
Easy assembly between heat sink and heat sink (or printed circuit board), assembly between above assembly and lighting cylinder, lighting cylinder-cover lens-cap, lighting cylinder-plate spring and easy to assemble LED downlight. Implemented so that it can be conducted to the lighting fixtures.
In addition, the lighting cylinder and the cap are formed in a screw structure, and the plate spring can be assembled without a separate screw or rivet, thereby reducing the production cost by reducing the assembly time during production. In addition, the diffuser plate made of glass, polycarbonate, or acrylic can be mounted at a certain range within the range of the light through and the screw feed distance of the cap, regardless of the thickness of the cover lens, thereby improving glare from the LED and when the LED is turned on. The dot was made invisible.
In particular, the spring guide groove for inserting the plate spring for embedding in the ceiling is formed in an integral structure on the inner surface of the lighting cylinder to reduce the production cost by eliminating the need for fixing with screws or rivets. The leaf spring shape is designed in a bending structure to be fixed in the spring guide groove without play, and can be designed in a concave-convex shape according to the intention of the operator.
By devising as described above, the light distribution characteristic of the LED downlight of the ceiling-embedded structure was improved by maximizing the light distribution area of the lighting as much as possible.

Description

The stucture of recessed LED downlight housing

The present invention relates to a ceiling-mounted LED downlight lighting fixture structure,

In detail, a heat sink that performs a heat dissipation function, an LED module consisting of an LED and a printed circuit board, a heat sink that transfers heat generated by the LED module to a heat sink,

In the downlight luminaire comprising a lighting cylinder having a structure that can be inserted into the heat sink, the LED module, the heat sink and the leaf spring, a cover lens and a cap for transmitting the light emitted from the LED module;

Heat sink with C-shaped screw groove for assembly with heat sink,

C-shaped screw groove for assembling heat sink, spring guide groove for assembling leaf spring, step (or screw shape) for mounting LED module and heat sink, and screw cylinder for assembling cap ,

Cap designed with screw shape for easy assembly of lighting cylinder-cover lens-cap,

It is a technical field of the LED downlight luminaire, characterized in that the mechanical mechanism for the leaf spring mounted on the illumination cylinder.

[Document 1] Patent Application No. 10-2010-0027840

[Document 1] Utility Model Application No. 20-2010-0003260

As described above, the present invention,

Regarding the ceiling mounted LED downlight luminaire which consists of a heat sink, an LED module, a heat sink, a light cylinder, a cover lens, a cap, and a leaf spring, and which can insert a leaf spring,

 The heat generated from the LED module is conducted and radiated through the heat sink through the heat sink, heat sink, lighting cylinder, cap, and leaf spring to the entire luminaire, thereby dramatically improving the illumination and life of the LED lighting. The assembly consisting of an LED module and a heat sink has a structure that can be easily assembled and assembled with the lighting cylinder.

In addition, in order to ensure that the assembly is in close contact with the illumination cylinder, the side surface portion of the heat sink is a male screw shape and the inner surface of the illumination cylinder is designed with a female screw shape. If necessary, the inner surface of the lighting cylinder has a stepped shape so that the heat sink can be fastened with a screw.

Then, to mount the downlight on the ceiling to form a spring guide groove structure for inserting the leaf spring on the inner surface of the illumination cylinder, and to have a screw shape so that the cover lens can be easily assembled between the illumination cylinder and the cap. .

The leaf springs are assembled to the light cylinder without any screws or rivets.

In order to solve the above problems,

The present invention forms a spring guide groove to insert the plate spring on the inner surface of the lighting cylinder for embedding the LED downlight lighting fixture on the ceiling to increase the diameter of the lighting cylinder to maximize the light distribution area emitted from the LED, Have the screw shape on the top of the light cylinder and the heat sink, or put the LED module and heat sink on the step of the light cylinder.

And the assembly consisting of heat sink, LED module and heat sink is designed to be easily assembled with the light cylinder.

In addition, the outer surface of the lower end of the illumination cylinder is processed into a screw shape to the inner surface of the cap to be assembled so that it can be assembled, the cover lens is sandwiched between the illumination cylinder and the cap and the illumination cylinder and the cap by turning Have a structure that can be assembled.

The leaf spring is designed with a concave-convex or bent structure so as to be in close contact with the spring guide groove of the lighting cylinder.

Conventional LED downlight luminaires are structured to attach coiled springs, torsion springs, leaf springs, fixed brackets, etc. to the outer surface of the light cylinders to be embedded in the ceiling. The light distribution efficiency of the light was not good because the diameter of the cover lens through which the light emitted from the light was transmitted was small and the light transmission area was narrow, and components such as screws and rivets were inevitably involved in assembling the equipment, which inevitably entails assembly costs. It was uneconomical.

The present invention has solved the problems described above, the entire luminaire was able to efficiently heat the heat generated from the LED, according to the purpose of the cover lens which is a diffusion plate made of glass, polycarbonate or acrylic, etc. The thickness of the inside is improved so that it can be mounted so that the glare generated from the LED and the dots are not visible when the LED is turned on.

Figure 1 shows an exploded view of the mechanism of the downlight lighting, which is an embodiment of the present invention.
Figure 2 shows a cross-sectional view of a heat sink having a heat dissipation function of the illumination of the downlight which is an embodiment of the present invention.
Figure 3 shows an enlarged shape of the upper end of the illumination cylinder of the downlight which is an embodiment of the present invention.
Figure 4 shows the shape of the illumination cylinder which is an embodiment of the present invention.
Figure 5 shows a stepped structure formed to mount the spring guide groove and the heat sink or printed circuit board formed on the inner surface of the illumination cylinder of the embodiment of the present invention.
Figure 6 shows the shape of the spring guide groove formed on the inner surface of the illumination cylinder of the embodiment of the present invention as seen from the outside of the illumination cylinder.
7 illustrates a stepped structure formed to mount a C-type screw groove formed on the inside of the illumination cylinder and a heat sink or a printed circuit board.
Figure 8 shows the outer surface shape of the cap which is an embodiment of the present invention.
Figure 9 shows the inner surface shape of the cap which is an embodiment of the present invention.
Figure 10 shows a cut surface of the cap which is an embodiment of the present invention.
11 is an enlarged cut surface of a cap which is an embodiment of the present invention.
Figure 12 illustrates a leaf spring shape which is an embodiment of the present invention.
Figure 13 shows the bent shape of the leaf spring which is an embodiment of the present invention.
Figure 14 shows the concave-convex shape of the leaf spring which is an embodiment of the present invention.
Figure 15 shows a state in which the leaf spring is mounted in the spring guide groove of the illumination cylinder of the embodiment of the present invention.

In general, the luminaire of the ceiling-mounted downlight has a diameter of the luminaire cylinder according to the diameter of the ceiling recessed hole such as 2 inches, 3 inches, 4 inches, 4,5 inches, 5 inches, 6 inches, 8 inches, and 10 inches. Do it differently.

For example, a 6-inch downlight must be able to be mounted on the 6-inch diameter of the ceiling recess, so in practice, the diameter of the 6-inch downlight must be smaller than this to secure it to the ceiling. Therefore, increasing the diameter of the LED downlight illumination cylinder as large as possible can increase the light distribution efficiency of the light emitted from the LED.

For reference, problems of the conventional LED downlight luminaires are relatively small in diameter due to the spatial volume of the coil-type springs, leaf springs, and fixing brackets attached to the outer surface of the lighting cylinder. Due to this, the area of the cover lens 11 is also narrowed, which limits the light distribution efficiency of the light emitted from the LED. At present, research and development of luminaires for maximizing the diameter of the lighting cylinder of the LED downlight is being actively conducted.

With reference to the accompanying drawings will be described in detail the implementation of the present invention.

Figure 1 shows a ceiling-mounted LED downlight lighting fixture according to the present invention,

Heat generated from the LED module consisting of the printed circuit board 4 and the LED 5 is conducted to the heat sink 3, and the heat sink 1 is coupled to the heat sink 3. If necessary, in the case of using a printed circuit board such as metal or ceramic material having excellent heat dissipation or thermal conductivity, the heat sink may be replaced.

An embodiment of the heat sink 1 may be manufactured in the shape as shown in FIG. 2, and may be implemented in various shapes according to heat dissipation characteristics.

Referring to the structure of the lighting cylinder 7 of the present invention,

Heat generated from the LED module consisting of the printed circuit board (4) and the LED (5), together with the heat sink (3) and heat sink (1), the lighting cylinder (7), cap (9), leaf spring (????) In order to conduct heat to the entire downlight luminaire consisting of) to have a heat dissipation so as to have a step 16 and a screw 14 structure on the inner surface of the lighting cylinder as shown in FIG. For reference, FIG. 3 is an enlarged view of FIG. 1.

The purpose of forming this step is to assemble the heat sink 3, the printed circuit board 4, or, if necessary, a printed circuit board made of a metal or ceramic material having excellent heat dissipation or thermal conductivity, by placing it on the step 16 of the illumination cylinder of FIG. This is to enable or close assembly of the heat dissipation plate 15 processed in the form of a screw 14 to the inner surface of the illumination cylinder.

The spring guide groove 18 is formed on the inner surface of the illumination cylinder 7 as shown in 18 of FIG. 4 to insert the leaf spring shown in FIG. 12 so as to maximize the light distribution area. . The role of the leaf spring (???) is used to fix the ceiling and in the present invention, the leaf spring (???) is also combined with the lighting cylinder (7) to have a heat dissipation function.

The C-type screw groove 17 of FIG. 4 is formed to assemble the heat sink 3, and may be assembled in the shape as shown in FIG. 3 instead of the C-type screw groove.

5 is an enlarged spring guide groove 18, and includes a stepped structure formed so that the heat sink 3 can be placed thereon, and FIG. 6 shows what is seen from the outer side of the illumination cylinder 7. Omitted.

7 is an enlarged C-type screw groove 17 to form a stepped structure to place the heat sink (3). For reference, the reason for the formation of the C-type screw groove is to reduce the processing cost by eliminating the need for additional thread processing.

Referring to the structure of the cap 9 which is an embodiment of the present invention,

FIG. 8 shows an outline view of a cap 9 which is an embodiment of the present invention, and FIG. 9 shows what is seen from the inside of the cap 9. 10 shows the cap 9 cut vertically.

The role of the cap 9 coupled to the lighting cylinder 7 is to be supported by ceiling finishes such as textiles, plywood, and gypsum board when the downlights are embedded in the ceiling, and a spring attached to the lighting cylinder 7 ( It is fixed by the support angle of ???, and the spring is held inside the ceiling and the cap is held outside the ceiling.

And it serves to mount a cover lens 11 of plastics such as glass, polycarbonate or acrylic to diffuse the light emitted from the LED.

On the inner side of the cap (9) was formed a screw thread (10) for assembly with the illumination cylinder (7), and to have a support (12) to support the cover lens (11).

Separate subsidiary materials such as screws, clamps, adhesives, etc. to fix or attach the light cylinder 7 and the cap 9 regardless of the thickness of the cover lens 11 within a certain range within the thread transfer distance for assembling the light cylinder 7 and the cap 9. It was possible to assemble without.

9, 10 and 11, the screw shape formed on the inner surface of the bar cap described above in Figure 1 is omitted.

The cover lens 11 generally uses a diffuser plate containing a diffusion material to prevent glare from LED light and a source of LED lighting. The glare phenomenon is reduced according to the thickness of the diffuser plate and the dot is lit when the LED is lit. Was not visible, and the assembly was possible within a certain range of thickness depending on the feeding distance of the thread formed on the illumination cylinder (7) and the cap (9).

Referring to the leaf spring (???) which is an embodiment of the present invention,

As shown in FIG. 12, when the leaf spring is inserted into the spring guide groove 18 of the lighting cylinder 7, the spring guide groove 18 is disposed in the spring guide groove 18 to solve the mechanical separation distance caused by the thickness of the leaf spring. Bending 23 was formed as shown in FIG. 13 to be in close contact. In some cases, as shown in Fig. 14, the spring may be embossed 24.

In addition, as shown in FIG. 12, α, which is a support angle 21, was formed to fix the leaf spring regardless of the thickness of the ceiling finishing material such as textile, plywood, gypsum board, and the supporting angle (21) according to the thickness of the ceiling finishing material. ) Can be different.

FIG. 15 illustrates that the plate spring is mounted on the illumination cylinder 7, and as shown in FIG. 13, when the plate spring is mounted on the illumination cylinder, the spring bending angle 22 β may be varied according to the horizontal tension. .

In addition, the plate spring inserted into the spring guide groove 18 is mounted on the stepped portion of the spring guide groove 18 by the heat sink 3 or the printed circuit board 4 to press the plate spring (???). To be fixed without separation. Conventional downlight luminaires are uneconomical by fixing the springs with screws or rivets, which involve related components and involve assembly costs.

Claims (10)

A heat sink 1 having a heat sink 3 or a C-shaped threaded groove 13 for coupling the heat sink 3 to the printed circuit board 4,
An illumination cylinder 7 having a C-shaped screw groove 17 for coupling the heat sink 3 or the heat sink 3 to the printed circuit board 4,
An illumination cylinder 7 having a step 16 structure for conducting heat generated from the LED 5 on the inner surface of the illumination cylinder to the illumination cylinder;
Illumination cylinder (7) having a spring guide groove (18) on the inner surface of the illumination cylinder,
The shape treated with screws 14 on the inner side of the upper end of the illumination cylinder 7, and screws 8 on the outer side of the lower end,
Cap 9 structure treated with screws 10 for assembly with the lighting cylinder,
With a cover lens 11 inserted between the illumination cylinder and the cap
Ceiling type downlight luminaire, characterized in that the configuration The method according to claim 1,
Downlight luminaire structure for assembling by turning the lighting cylinder (7) formed by the screws (8, 9) and the cap (9) The method according to claim 1,
A cap having a support (12) between the lighting cylinder (7) and the cap (9) by inserting the cover lens 11, which is a diffusion plate made of plastic, such as glass, polycarbonate, and acrylic, to be coupled The method according to claim 1,
Leaf spring structure mounted to the spring guide groove 18 formed on the inner surface of the illumination cylinder (7) The method according to claim 1,
Method of assembling by forming screws (15) on the inner surface screw 14 of the upper end of the lighting cylinder (7) and the side of the heat sink, and conducting heat generated from the LED module The method according to claim 3,
Mechanical structure that can be assembled without any additional materials for fixing and attachment regardless of the thickness of the cover lens 11 within a certain range within the thread feed distance for assembling the lighting cylinder 7 and the cap 9 The method of claim 4,
Bending (23) of the spring inserted into the spring guide groove (18) to be mechanically in close contact The method of claim 4,
Unevenness (24) of the spring inserted into the spring guide groove (18) to be mechanically in close contact The method of claim 4,
Leaf spring formed with bend angle 22 according to horizontal tension The method of claim 4,
Method to press the leaf spring inserted into the spring guide groove 18 by the heat sink 3 or the printed circuit board 4

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