KR20150053470A - Fluorescent lamp type led lamp - Google Patents

Abstract

The present invention relates to a fluorescent lamp type LED lamp which includes a tube body (10) which is composed of a heat radiation frame (11) with a heat radiation fin (11a) and a diffusion cap (16) which is mounted on the heat radiation frame (11) and is formed with an entire tube shape, an LED module (20) which is installed on the heat radiation frame (11) and is composed of a plurality of LEDs (22) mounted on a PCB (21), a converter substrate (30) which is installed on the heat radiation frame (11) and converts the applied AC into DC for driving the LED module (20), a socket (40) which is combined with both ends of the tube body (10) and supplies power to the converter substrate (30), and a check valve (50) which discharges moisture from the tube body (10) to the outside and prevents external moisture from being inputted to the tube body (10).

Description

Fluorescent type LED lighting device {FLUORESCENT LAMP TYPE LED LAMP}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluorescent lamp type LED lighting apparatus, and more particularly, to a fluorescent lamp type LED lighting apparatus which can prevent corrosion even in a humid environment and thereby extend service life.

In general, a conventional fluorescent lamp applies a fluorescent material to the inner wall of a mercury discharge tube, and argon gas and a small amount of mercury are put in the inside of the mercury discharge tube, and then a voltage is applied to generate light by discharge of gas. Such a fluorescent lamp is disadvantageous in that the mercury discharge tube is sufficiently sealed, the process is troublesome, and there is a problem of environmental pollution due to the mercury material, and it takes time until the light is emitted.

Fluorescent lamp type LED lighting apparatuses which have advantages of high processing speed and low power consumption due to the problems of fluorescent lamps have been developed. Such LED lighting apparatuses are advantageous because they do not use heavy metals such as mercury, It is attracting attention as a light source.

However, the LED lighting device has a light source in which a plurality of LEDs are mounted on a PCB substrate, and the semiconductor LEDs are very vulnerable to heat. Accordingly, a structure for effectively dissipating the heat generated from the LED light source in implementing the LED lighting apparatus is required. A fluorescent lamp type LED lighting device to which such a heat radiation structure is applied is disclosed in the prior art in Patent Publication No. 10-2011-0020477.

On the other hand, LEDs have a lifespan of more than 50,000 hours, but in practical terms, the operating time of LED lighting devices is significantly smaller than the lifetime of LEDs. This is due to damage to the fine patterns or micro-elements of the PCB substrate that supply power to the LED, which is mostly caused by humidity-induced corrosion. Particularly, when the LED lighting device is installed in a place with high humidity, for example, in a high humidity basement, a house for growing livestock, or a house where vegetables are grown, the humidity changes rapidly and the corrosion proceeds more quickly. Accordingly, there is a need to develop a technique for preventing the LED module from being corroded under external humidity conditions in the fluorescent lamp type LED lighting device.

It is an object of the present invention to provide a fluorescent lamp type LED lighting device which is capable of increasing the service life by minimizing the occurrence of corrosion in the LED module even when the humidity of the outside is high or the humidity is large, The purpose.

Another object of the present invention is to provide a fluorescent lamp type LED lighting device capable of removing odor, bacteria, dust, etc. in the air in the room air.

In order to achieve the above object, a fluorescent lamp type LED lighting apparatus according to the present invention comprises a heat radiation frame 11 having a heat radiation fin 11a and a diffusion cap 16 mounted on the heat radiation frame 11, A tubular body 10 generally in the form of a tube; An LED module 20 installed on the heat radiating frame 11 and composed of a plurality of LEDs 22 mounted on a PCB substrate 21; A converter board (30) installed in the heat dissipating frame (11) for converting an applied AC power into a DC power for driving the LED module (20); A socket (40) coupled to both ends of the tube body (10) to supply power to the converter board (30); And a check valve (50) for discharging moisture inside the tube body (10) to the outside and preventing external moisture from flowing into the tube body (10).

The LED module 20 further includes an anion generator 60 installed in the tube body 10 to generate an anion by heat generated when the LED module 20 operates.

The ribs 18 for pressing and fixing the PCB substrate 21 when the diffusion cap 16 is coupled to the heat radiating frame 16 are formed at both ends of the inner circumferential surface of the diffusion cap 16, ). And an elastic contact end 19 formed at the lower end of the rib 18 to closely contact the PCB substrate 21.

The check valve 50 is coupled to the valve coupling hole 42 of the socket 40 and includes a valve body 51 having an inlet port 51a formed at one side thereof, A check ball 52 built in the valve body 51 for selectively opening and closing the inlet port 51a and a spring 53 for elastically pressing the check ball 52 toward the inlet port 51a, .

In the present invention, the flow path holes 13a and 21a are formed on the PCB substrate 21 and the seating end 13, respectively.

According to the present invention, it is possible to discharge the moisture inside the tube body to the outside and prevent moisture from entering into the tube body, even if the humidity of the outside is high or the humidity change is large. It is possible to minimize the occurrence of shortage of life of the LED lighting apparatus.

In addition, an anion is generated when the LED module is operated, so that odor, bacteria, dust, etc. in the indoor air in which the LED lighting device of the present invention is installed can be removed.

1 is a perspective view of a fluorescent lamp type LED lighting apparatus according to the present invention,
Fig. 2 is a side view of the fluorescent lamp type LED lighting apparatus of Fig. 1,
Fig. 3 is a perspective view showing a part of the fluorescent lamp type LED lighting apparatus of Fig. 1,
4 is a cross-sectional view taken along line IV-IV 'of the fluorescent lamp type LED lighting apparatus of FIG. 1,
Figures 5A and 5B are cross-sectional views of the check valve of Figure 3,
FIG. 6 is a view for explaining the operation of the fluorescent-type LED lighting apparatus of FIG. 1; FIG.

Hereinafter, a fluorescent lamp type LED lighting apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a fluorescent lamp type LED lighting apparatus according to the present invention, FIG. 2 is a side view of the fluorescent lamp type LED lighting apparatus of FIG. 1, 4 is a cross-sectional view taken along line IV-IV 'of FIG. 1, and FIG. 6 is a cross-sectional view of a fluorescent lamp type LED lighting device of FIG. 1, Fig. 8 is a view for explaining the operation of the apparatus.

As shown in the figure, the fluorescent lamp type LED lighting apparatus according to the present invention comprises a heat dissipating frame 11 having a heat dissipating fin 11a and a diffusion cap 16 mounted on the heat dissipating frame 11, (10); An LED module 20 installed in the heat radiation frame 11 and composed of a plurality of LEDs 22 mounted on the PCB substrate 21; A converter board (30) installed in the heat dissipating frame (11) for converting an applied AC power into a DC power for driving the LED module (20); A socket (40) coupled to both ends of the tube body (10) to supply power to the converter board (30); A check valve 50 for discharging moisture inside the tube body 10 to the outside and preventing external moisture from flowing into the tube body 10; And an anion generator 60 installed in the tube body 10 and generating negative ions by heat generated when the LED module 20 is operated.

Each of the heat dissipating frame 11 and the diffusion cap 16 has a semi-cylindrical shape as a whole and forms a cylindrical shape like a fluorescent lamp when coupled to each other.

A groove 12 is formed at both edges of the heat dissipating frame 11 as shown in Figs. 3 and 4, and a hook (not shown) 17 are elongated. With this structure, the diffusion cap 16 can be coupled to the heat dissipating frame 11 by fitting the hook 17 into the groove 12.

The heat radiating frame 11 is for emitting the heat generated from the LED module 20 to the outside. As shown in FIG. 4, on the outer circumferential surface, a large contact area with the air is provided to increase the heat radiation efficiency. The radiating fin 11a is formed. The heat radiating frame 11 is made of an aluminum material having excellent thermal conductivity and good corrosion resistance.

A guide groove for guiding the position of the PCB substrate 21 is formed on the upper side of the heat dissipating frame 11 and a flat mounting end 13 is formed on the bottom of the guide groove to closely contact the back surface of the PCB substrate 21.

A frame space (14) for generating a flow of air is formed inside the heat radiation frame (11). The converter board 30 may be embedded in the frame space 14.

The diffusion cap 16 protects the front of the LED illumination device of the present invention while diffusing the light emitted from the LED module 20. The diffusion cap 16 is made of a material excellent in LED color reproduction, high in anti-glare, high impact resistance and flame retardancy, and excellent in light diffusion efficiency, and is made of VEGAREX, VEGA CHEM or PVC, PE And a synthetic resin in which acrylic is mixed with a light diffusing agent may be used.

At both ends of the inner circumferential surface of the diffusion cap 16, ribs 18 are formed as shown in Figs. 3 and 4. The ribs 18 serve to press and fix the PCB substrate 21 of the LED module to be described later when the diffusion cap 16 is coupled to the heat radiation frame 16. [

Further, at the lower end of the rib 18, there is formed an elastic contact end 19 which is in close contact with the PCB substrate 21. It is preferable that the elastic adhesive edge 19 is made of silicone rubber resistant to heat and the gap between the diffusion cap 16 and the heat radiation frame 11 when the elastic adhesive edge 19 is in close contact with both side edges of the PCB substrate 21 Lt; / RTI > Thereby preventing external moisture from entering the space inside the diffusion cap 16.

The LED module 20 includes a PCB substrate 21 closely attached to the mounting end 13 of the heat radiation frame 11 and a plurality of LEDs 22 mounted at a predetermined interval on the PCB substrate 21, An electrode pattern (not shown) for supplying power to the LED 22 is formed on the upper surface of the substrate 21.

Meanwhile, as shown in FIGS. 3 and 4, the flow path holes 13a and 21a are formed on the PCB substrate 21 and the mounting end 13, respectively. These flow holes 13a and 23a allow the space between the frame space 14 of the heat dissipating frame 11 and the inner space of the diffusion cap 16 to communicate with each other, The flow path is formed.

The converter board 30 performs a power control function of converting the AC power inputted through the socket 40 to a DC power for LED driving and supplying the DC power to the LED module 20. The converter board 30 is formed with a circuit pattern for transmitting power supply and control signals, and various power supply control components 31 are mounted.

The socket 40 is coupled to both ends of the tube body 10 and is provided with a terminal 41 for supplying power to the converter board 30. 3, a valve coupling hole 42 is formed in the socket 40, and a check valve 50 is coupled to the valve coupling hole 42. As shown in FIG.

The check valve 50 is for discharging the moisture inside the tube body 10 to the outside and preventing external moisture from flowing into the tube body 10. The check valve 50 is connected to the valve engagement hole 42 of the socket 40 and includes a valve body 51 having an inlet port 51a formed at one side thereof and an inlet port 51a built in the valve body 51 A check ball 52 selectively opened and closed and a spring 53 built in the valve body 51 and elastically pressing the check ball 52 toward the inlet port 51a. With this structure, when the check ball 52 blocks the inlet port 51a, the check valve 50 is closed as shown in FIG. 5A. When high air pressure is applied to the inlet port 51a, the check valve 50 is opened and air can flow as shown in FIG. 5B. 6, the check valve 50 is coupled to the valve engagement hole 42 so that the inlet port 51a faces the inside of the tube body 10, strictly, the frame space 14 of the heat radiation frame, do.

The negative ion generating part 60 generates negative ions by heat generated by the operation of the LED module 20 and is installed in the back surface groove 11b formed on the back surface of the heat radiating frame 11. [ The anion generator 60 is composed of 20% by weight of the anion material and 50 to 30% by weight of the loess and the other ingredients, wherein the anion material is an antiseptic ceramic and the deodorizer material is an internationally recognized grace Grace) method. As a result, an anion of 600 ico / cc per second can be released semi-permanently, and these anions remove odors, bacteria and dust in the room air.

Next, the operation of the above-described fluorescent lamp type LED lighting apparatus will be described.

As shown in Fig. 6, the check valve 50 is arranged such that the inlet port 51a faces the inside of the tube body 10. [0052] As shown in Fig. The check ball 52 closes the inlet port 51a by the spring 53 so that the check valve 50 is closed and the moisture from the outside is prevented from flowing into the inside of the tube body 10. [ do.

On the other hand, when the LED module 20 is operated to generate heat, the air pressure increases as the temperature of the air inside the tube body 10 increases, and the air pressure pushes the check ball 52 in a direction separating from the inlet 51a . The air having moisture inside the tube body 10 is discharged to the outside through the gap between the inlet 51a and the check ball 52 and the valve body 51. [

When the operation of the LED module 20 is stopped (when the fluorescent lamp type LED lighting apparatus is turned off, heat is no longer generated and the air temperature inside the tube body 10 is cooled) The check valve 53 prevents the check valve 52 from closing the inlet port 51a to allow the air having the moisture from the outside to flow.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10 ... tube body 11 ... heat radiating frame
11a ... Radiating fins 12 ... Groove
13 ... seat 14 ... frame space
16 ... diffusion cap 17 ... hook
18 ... rib 19 ... elastic contact end
20 ... LED module 21 ... PCB board
22 ... LED 30 ... converter board
40 ... socket 41 ... terminal
42 ... Valve coupling hole 50 ... Check valve
51 ... valve body 51a ... inlet
52 ... check ball 53 ... spring
60 ... Negative ion generator

Claims (6)

A tube body 10 constituted by a heat dissipating frame 11 in which a radiating fin 11a is formed and a diffusion cap 16 mounted in the heat dissipating frame 11 so as to form a tube as a whole;
An LED module 20 installed on the heat radiating frame 11 and composed of a plurality of LEDs 22 mounted on a PCB substrate 21;
A converter board (30) installed in the heat dissipating frame (11) for converting an applied AC power into a DC power for driving the LED module (20);
A socket (40) coupled to both ends of the tube body (10) to supply power to the converter board (30); And
And a check valve (50) for discharging moisture inside the tube body (10) to the outside and preventing external moisture from flowing into the tube body (10) . The method according to claim 1,
Further comprising an anion generator (60) installed in the tube body (10) to generate an anion by heat generated when the LED module (20) is operated. The method according to claim 1,
And a rib 18 formed at both ends of the inner circumferential surface of the diffusion cap 16 for pressing and fixing the PCB substrate 21 when the diffusion cap 16 is coupled to the heat radiating frame 16 Wherein the LED lighting device is a fluorescent lighting device. The method of claim 3,
Further comprising an elastic contact end (19) formed at a lower end of the rib (18) and closely contacting the PCB substrate (21). 2. The apparatus according to claim 1, wherein the check valve (50)
A valve body 51 coupled to the valve coupling hole 42 of the socket 40 and having an inlet port 51a formed at one side thereof and a valve body 51 built in the valve body 51 for selectively opening and closing the inlet port 51a, , And a spring (53) embedded in the valve body (51) and elastically pressing the check ball (52) toward the inlet port (51a). The method according to claim 1,
Wherein a flow path hole (13a) (21a) is formed in the PCB substrate (21) and the mounting end (13) to be mutually engaged.

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