KR200450478Y1 - LED lamp - Google Patents

Abstract

The present invention relates to an LED lamp, and more particularly, in an LED lamp configured in the form of a light bulb, comprising a radiator interposed between an LED module and a driving circuit, and including a radiator interposed between the radiator and the driving circuit. The present invention relates to an LED lamp that can effectively dissipate heat generated from an LED module by providing an air cap for smoothing air circulation in a heat dissipation channel formed between heat dissipation fins.

The LED lamp according to the present invention, the LED module consisting of a substrate formed with an electrode circuit, and a plurality of LED chips mounted on the electrode circuit on the substrate; A lens mounted to the front of the LED module; A heat sink mounted to a rear portion of the LED module; An air cap coupled to a rear end of the heat sink to form an air circulation passage for discharging heat accumulated in the heat sink; A socket connected to the air cap and having an electrode formed at one side thereof to receive driving power from the outside; And a driving circuit mounted inside the socket to drive the LED mounted on the LED module, wherein the air cap includes: a cylindrical body having an upper side opened; A plurality of air outlets formed through the side of the body; And an inner wall provided inside the body, spaced apart from the inner diameter of the body by a predetermined distance, and formed in a cylindrical shape extending a predetermined length in a vertical direction from the bottom of the body, to which the heat sink is connected. .

LED lamp, heat dissipation, air cap, air path, air gap

Description

LED lamp {LED lamp}

The present invention relates to an LED lamp, and more particularly, in an LED lamp configured in the form of a light bulb, comprising a radiator interposed between an LED module and a driving circuit, and including a radiator interposed between the radiator and the driving circuit. The present invention relates to an LED lamp that can effectively dissipate heat generated from an LED module by providing an air cap for smoothing air circulation in a heat dissipation channel formed between heat dissipation fins.

Currently, discharge lamps such as fluorescent lamps, incandescent lamps and halogen lamps are used as light sources for indoor lighting in homes and offices. Since the discharge lamp has a high driving voltage, the energy consumption is large due to the boost of the electric power, and when discharged, the discharge lamp discharges discharge gas such as mercury, which is harmful to the human body or the environment.

In particular, in the European Union, heavy metals such as lead, mercury, cadmium, hexavalent chromium (Cr ⁺⁶ ), and hazardous substances such as PBB (PolyBromide Binpenyl) and PBDE (PolyBrominated Diphenyl Ether) Restoring the use of Hazardous Substances (RoHS) and the Waste Electrical and Electronic Equipment Directive (WEEE) that require producers to bear the costs of recycling waste electrical and electronic products. The law was enacted and has been in effect since July 1, 2006.

Accordingly, the necessity of research and development of a new luminaire that can replace a luminaire such as a fluorescent lamp currently used is emerging.

In addition, with the rapid development of the technology related to light emitting diodes (LEDs), white LEDs emitting white light using blue LEDs and phosphors have emerged. It is an environmentally friendly light source that has low power, long life, no harmful waves such as ultraviolet light, and no mercury or discharge gas, and has been spotlighted as a powerful means to replace the existing light source.

However, these LEDs emit a large amount of heat while converting power into light, which causes the LED to deteriorate, shorten its lifespan, and damage the driving circuit for driving the LED, thereby dissipating heat generated from the LED. A heat dissipation structure is necessary.

In particular, LED lamps are being developed to replace light sources in the form of bulbs such as incandescent lamps and halogen lamps, which are accumulated in the interior of LED lamps because they are embedded in walls such as ceilings. There is a need for a heat dissipation structure for heat dissipation more effectively.

Therefore, the present invention, in order to solve the above problems, a plurality of LED mounted LED module and a driving circuit for driving the LED is mounted apart from each other, and a heat sink for radiating heat generated from the LED module The driving circuit effectively dissipates heat generated by the LED module between the LED module and the driving circuit, and also through the air cap that forms an air circulation path between the heat sink and the driving circuit. It is to provide an LED lamp that can be discharged to improve heat dissipation.

The LED lamp according to the present invention, the LED module consisting of a substrate formed with an electrode circuit, and a plurality of LED chips mounted on the electrode circuit on the substrate; A lens mounted to the front of the LED module; A heat sink mounted to a rear portion of the LED module; An air cap coupled to a rear end of the heat sink to form an air circulation passage for discharging heat accumulated in the heat sink; A socket connected to the air cap and having an electrode formed at one side thereof to receive driving power from the outside; And a driving circuit mounted inside the socket to drive the LED mounted on the LED module, wherein the air cap includes: a cylindrical body having an upper side opened; A plurality of air outlets formed through the side of the body; And an inner wall provided inside the body, spaced apart from the inner diameter of the body by a predetermined distance, and formed in a cylindrical shape extending a predetermined length in a vertical direction from the bottom of the body, to which the heat sink is connected. .

According to the LED lamp according to the present invention, through the air cap to form a heat dissipation channel to discharge the heat accumulated between the radiation radiating fins formed on the heat dissipation to improve the heat dissipation performance and heat transmitted to the heat dissipation through this Since the transmission to the driving circuit mounted inside the socket can be blocked, there is an effect that the life of the lamp can be improved by preventing the LED and the driving circuit from being deteriorated by the heat generated from the LED.

Hereinafter, embodiments of the present invention will be described in detail, but the present invention is not limited to the following embodiments unless departing from the gist of the present invention.

1 is an exploded perspective view showing the configuration of the LED lamp according to the present invention, Figure 2 is a cross-sectional view showing the internal configuration of the LED lamp according to the present invention, will be described in relation to each other.

LED lamp according to the present invention, the LED module 210 is composed of a substrate 212, the electrode circuit is formed, a plurality of LED chips 214 mounted on the electrode circuit on the substrate 212, LED module 210 A lens 100 mounted on a front portion of the lens 100 to diffuse light emitted from the LED module 210 to the outside, a heat sink 300 mounted on a rear portion of the LED module 210, and a heat sink 300 of the lens 100. The air cap 400 is coupled to the rear end and forms an air circulation passage for releasing heat accumulated in the heat sink 300, and is mounted in the socket 600 and the socket 600 connected to the air cap 400. And a driving circuit 500 for driving the LED chip 214 mounted on the LED module 210.

The LED module 210 used as a light source of the lamp is attached to the substrate 212 and the electrode circuit on the substrate 212 and the electrode circuit is formed to electrically connect the LED chip 214 is electrically connected to each other It is composed of a plurality of high-power LED chip 214. Here, the substrate 212 may be made of a resin-based material which is commonly used, but a substrate having a high thermal conductivity metal may be used to quickly transfer heat generated from the LED chip 214 to the radiator 300. Can also be used.

The lens 100 is mounted on the front part of the LED module 210 to inject light emitted from the LED chip 214 to diffuse to the outside. This is because, unlike the discharge lamp, the LED chip 214 has a small angle of light diffusion, so that the light is irradiated by mounting the convex lens 100 in front of the LED module 210, that is, the direction in which the light is emitted. This is to increase the area of illumination by expanding the angle to be more efficient lighting effect can be obtained.

In addition, a transparent glass may be used as the material of the lens 100 to improve light transmittance, opaque glass may be used to prevent glare, and glass of various colors may be used to exhibit various lighting effects. .

The LED module 210 and the lens 100 may be coupled to each other by a ring-shaped fixing device 200. The LED module 210 is seated in the fixing device 200, and then mounted on the fixing device 200. It can be integrated by attaching the lens 100.

The heat dissipator 300 has a plurality of hollows 310 are formed in the cylindrical body, the body surface has a plurality of heat dissipation fins along the longitudinal direction of the heat dissipator 300 to improve the heat dissipation effect by increasing the surface area ( 320 is radially formed, and a plurality of screw grooves 322 are formed between the heat dissipation fins 320 to fix the heat dissipation member 300 to the LED module 210 and the air cap 400. It is.

The radiator 300 is formed of a metal material having high thermal conductivity, for example, may be formed by an extrusion molding method using aluminum.

The air cap 400 is provided between the heat sink 300 and the socket 600 so that heat generated from the LED module 210 is mounted inside the socket 600, that is, the socket 600 through the heat sink 300. Blocking the transmission to the driving circuit 500. In addition, the air cap 400 is connected to the form surrounding the rear end portion of the radiator 300 by mounting the radiator 300 inside the body between the radiating fins 320 formed on the surface of the radiator 300. By forming the formed space and the air circulation passage so that the heat accumulated in the radiator 300 can be discharged.

Detailed structure of the air cap 400 will be described in detail later with reference to the accompanying drawings.

The socket 600 has a screw thread or stepped portion formed at an upper side thereof so as to be coupled to a lower end of the air cap 400 along an inner diameter, and an electrode threaded along an outer diameter at a lower side thereof so as to receive driving power from the outside. 610 is formed, and a hollow portion 310 is formed therein for mounting the driving circuit 500 for driving the LED.

The driving circuit 500 is mounted in the socket 600 and configured to be electrically connected to the electrode 610 formed under the socket 600 in the socket 600, and radiates heat from the LED module 210. It may be electrically connected through a wire passing through the sieve 300 and the air cap 400.

Hereinafter, in the LED lamp according to the present invention, a configuration of the air cap 400 mounted between the radiator 300 and the socket 600 will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing the configuration of the air cap 400 constituting the LED lamp according to an embodiment of the present invention, Figure 4 is a heat discharge from the LED module to the radiator in the LED lamp according to the present invention is released The figure shows the state.

Referring to FIG. 3, the air cap 400 has a cylindrical body 410 having an open upper side, a plurality of air outlets 416 formed through the side of the body 410, and inside the body 410. It is provided, and extends a predetermined length in the vertical direction from the bottom plate 410b of the body 410 is configured to include an inner wall 420 formed in a cylindrical shape.

The body 410 is composed of a disc-shaped bottom plate 410b and an outer wall 410a vertically extending around the bottom plate 410b, and the bottom plate 410b has a plurality of through holes 411 used as a passage for wiring. Is formed, and a plurality of air outlets 416 formed through the outer wall 410a are formed in the outer wall 410a.

In addition, the plurality of air outlets 416 formed on the outer wall 410a of the body 410, so that the heat transferred from the LED module 210 to the heat sink 300 when the LED lamp is assembled can escape. This is to perform effective heat dissipation.

On the outer wall 410a of the body 410, a stepped portion is formed to cover a predetermined thickness of one side of the heat sink 300, and a lower step or thread for connecting the socket 600 to the lower side of the outer wall 410a. Is formed.

The bottom plate 410b of the body 410 is formed with a minimum number of through holes 411 to be used as a passage for wiring, so that heat transmitted from the LED module 210 to the heat sink 300 is transferred to the socket 600. It can block the transmission to the driving circuit 500 mounted therein.

The inner wall 420 formed inside the outer wall 410a extends a predetermined height from the bottom plate 410b of the body 410 so as to seat the heat sink 300, and is lower than the outer wall 410a. .

In this configuration, when the radiator 300 and the air cap 400 are coupled to each other, the inner wall 420 seats the radiator 300 to space the bottom surface of the radiator 300 and the air cap 400 by a predetermined distance. The air gap 422 is formed, and the outer wall 410a surrounds a portion of the rear end of the radiator 300 by a predetermined height to form an air path 412 between the outer wall 410a and the inner wall 420.

Herein, the air gap 422 secures a predetermined space between the hollow part 310 inside the heat sink 300 and the bottom plate 410b of the air cap 400 so that heat accumulated in the hollow part 310 is stored in the socket 600. The air path 412 is prevented from being transmitted to the driving circuit 500 therein to some extent, and the air path 412 is connected to the space between the heat dissipation fins 320 formed on the surface of the heat dissipator 300 so that the air is as shown in FIG. By forming a passage that can be circulated to allow the heat transferred to the radiator 300 to escape to the air outlet 416 of the outer wall 410a through the air path 412.

A plurality of screw grooves 414 are formed between the inner wall 420 and the outer wall 410a to connect the radiator 300 and the air cap 400 to each other.

The body 410 may be formed of a plastic or resin-based material having low thermal conductivity to prevent heat from being transferred to the driving circuit 500 mounted in the socket 600 through the air cap 400.

Through such a configuration, heat transmitted from the LED module 210 to the heat sink 300 may be discharged through the air cap 400 to improve the heat dissipation effect, and a predetermined space inside the heat sink 300 is provided. It is possible to obtain a more efficient heat dissipation effect by blocking the heat sink 300 and the driving circuit 500 at the same time.

5 and 6 are perspective views showing another configuration of the air cap constituting the LED lamp according to another embodiment of the present invention.

Referring to FIG. 5, the air cap is formed in the same structure as that of the air cap 400 shown in FIG. 3 except for the shape of the inner wall 710 formed inside the outer wall of the body.

Here, the inner wall 710 formed inside the outer wall of the body penetrates the inner wall 710 at a position corresponding to the air outlet formed in the outer wall, and a plurality of air used as an air circulation passage to the inside and the outside of the inner wall 710. The circulation passage 712 is formed.

The air circulation passage 712 connects the air gap formed inside the inner wall 710 and the air path formed between the inner wall 710 and the outer wall to each other so that the air in the air gap passes through the air path to the outside through the air outlet. To be discharged.

In addition, referring to Figure 6, the air cap is formed in the same structure as the air cap 400 shown in Figure 3 differs only in the shape of the inner wall (720a, 720b, 720c) formed inside the outer wall of the body.

Here, the inner walls 720a, 720b, and 720c formed inside the outer wall of the body are composed of a plurality of inner walls 720a, 720b, and 720c having a predetermined interval, and the space between the inner wall 720a and the inner walls 720b and 720c. Through the air gap 422 formed to the inside of the inner wall (720a, 720b, 720c) and the air path 412 formed to the outside of the inner wall (720a, 720b, 720c) to form an air circulation passage through which air can be circulated Done.

Through this configuration, heat accumulated in the hollow part 310 of the heat dissipator 300 may be discharged to the outside through the air path 412, thereby further improving the heat dissipation effect.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the embodiments described, but should be defined by equivalents of the claims as well as the utility model registration claims described below.

1 is an exploded perspective view showing the configuration of an LED lamp according to the present invention.

Figure 2 is a cross-sectional view showing the internal configuration of the LED lamp according to the present invention.

Figure 3 is a perspective view showing the configuration of the air cap constituting the LED lamp according to the present invention.

4 is a view showing a state in which heat transferred from the LED module to the radiator in the LED lamp according to the present invention is released.

5 and 6 are a perspective view showing another configuration of the air cap constituting the LED lamp according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: lens 200: fixing device

210: LED module 212: substrate

214: LED chip 300: the heat sink

310: hollow part 320: heat dissipation fin

322, 414: thread groove 400: air cap

410: body 410a: outer wall

410b: base plate 411: through hole

412: air path 416: air outlet

420, 720a, 720b, 720c: inner wall 422: air gap

500: driving circuit 600: socket

610: electrode 710: air circulation passage

Claims (5)

An LED module comprising a substrate on which an electrode circuit is formed, and a plurality of LED chips mounted on the electrode circuit on the substrate; A lens mounted to the front of the LED module; A heat sink mounted to a rear portion of the LED module; An air cap coupled to a rear end of the heat sink to form an air circulation passage for discharging heat accumulated in the heat sink; A socket connected to the air cap and having an electrode formed at one side thereof to receive driving power from the outside; And A driving circuit mounted inside the socket to drive the LED mounted on the LED module; Consists of including The air cap, A cylindrical body having an upper side open; A plurality of air outlets formed through the side of the body; An inner wall provided inside the body, spaced apart from the inner diameter of the body by a predetermined distance, and formed in a cylindrical shape extending in a vertical direction from a bottom of the body in a vertical direction, to which the radiator is connected; LED lamp comprising a. The method of claim 1, The heat sink, A hollow part is formed inside the body, and the body surface is a LED lamp, characterized in that a plurality of radiating fins are formed radially along the longitudinal direction of the heat sink. delete The method of claim 1, On the bottom of the air cap, LED lamp, characterized in that a plurality of through-holes used as a passage of the wiring is formed. The method of claim 1, On the inner wall of the air cap, LED lamp, characterized in that the air circulation passage for the circulation of air between the inside and outside of the inner wall.

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