KR20100128266A - Lighting apparatus using white light led - Google Patents

Abstract

PURPOSE: A lighting apparatus using a white LED is provided to improve color rendering and definition by additionally outputting light of a wavelength for an optic nerve. CONSTITUTION: White LEDs(1) emit light of a first peak within a wavelength of 440 to 460 nm and a second peak within a wavelength of 520 to 600 nm. First LEDs emit light of a third peak within a wavelength of 492 to 500 nm for improving definition. Second LEDs(3) emit light of a fourth peak within the wavelength of 610 to 625 nm for improving color rendering. The white LEDs, the first LEDs, and the second LEDs are arranged on a substrate(4). A driving device drives the white LEDs, the first LEDs, and the second LEDs. A wiring(6,7) connects the substrate with the driving device.

Description

Lighting Apparatus Using White Light LED

The present invention relates to a luminaire using a white light LED, and more particularly, it is not output from a luminaire using a white light LED, but adds light of an essential wavelength required for the visual activity of the human optic nerve in natural light. The present invention relates to a luminaire capable of improving color rendering and sharpness.

As a main lighting device for public facilities or homes, lighting fixtures using three-wavelength lamps have been widely used, and recently, many lighting apparatuses using LEDs, which consume almost half the level of power consumption compared to three-wavelength lamps, have been developed and used.

On the other hand, natural light (sunlight) is emitted evenly over the entire wavelength range of 380-780 nm, and human visual activity has been adapted to this natural light, so when looking at the objects that the natural light shines on, humans feel comfortable and their vision is also protected. Becomes.

In addition, it is important to improve the color rendering property, which is the same level as the color under natural light, and to make it look the same as the color under natural light.

Therefore, in the conventional LED lighting apparatus, attempts have been made to improve color rendering properties by combining LEDs of various wavelengths so as to be close to natural light, but it is difficult to manufacture LEDs of each wavelength in terms of unit cost or yield problems in manufacturing processes. In recent years, it is common to construct a lighting apparatus using a plurality of white (light) LEDs, which are advantageous in terms of manufacturing cost or yield. Such white (light) LEDs are mainly manufactured by combining yellow phosphors with blue LEDs.

By the way, the white light LED has a spectral distribution as shown in Fig. 1, and generally emits light having a first peak value at 440-460 nm wavelength and a second peak value at 520-600 nm wavelength.

However, such white light LEDs have many wavelengths that exist in natural light but are not emitted by white light LEDs, resulting in poor color rendering (the CRI of the color rendering index is 65-75).

The present invention, in view of the problems of the lighting fixture using the white light LED as described above, while using a low-cost white light LED as the main light source, provides a lighting fixture that can improve the color rendering and sharpness.

In order to achieve the technical problem of the present invention as described above, in one embodiment of the invention, in the LED lighting fixture using a white light LED,

White light LEDs 1 for emitting a light having a first peak in the 440-460 nm wavelength range and a second peak in the 520-600 nm wavelength range as a main light source;

First LEDs 2 emitting light having a third peak value in a wavelength range of about 492-500 nm to improve sharpness as an auxiliary light source;

Second LEDs 3 for emitting color having a fourth peak in the wavelength range of about 610-625 nm to improve color rendering as an auxiliary light source;

A substrate (4) on which the white light LEDs (1), the first LEDs (2), and the second LEDs (3) are disposed;

A driving device (12) for driving the white light LEDs (1), the first LEDs (2) and the second LEDs (3);

It characterized in that it comprises a wiring (6, 7) connecting between the substrate 4 and the drive device (12).

In another embodiment of the present invention, in the LED lamp using the white light LED,

An external socket 21 for receiving AC power;

White light LEDs (23) disposed at the bottom of the LED lamp and emitting light having a first peak in the 440-460 nm wavelength range and a second peak in the 520-600 nm wavelength range as a main light source;

First LEDs 24 disposed at a lower end of the LED lamp and emitting light having a third peak value in a wavelength range of about 492-500 nm to improve clarity as an auxiliary light source;

Second LEDs 25 disposed at a lower end of the LED lamp and emitting light having a fourth peak in a wavelength range of about 610-625 nm to improve color rendering as an auxiliary light source;

A driving device 27 for driving the white light LEDs 23, the first LEDs 24, and the second LEDs 25;

A substrate on which the white light LEDs 23, the terminals of the first LEDs 24, the second LEDs 25, and the driving device 27 are disposed and receive AC power from the external socket 21. It characterized by including (26).

When the present invention is used as described above, it is not output from a luminaire using a white light LED, but by additionally outputting light of an essential wavelength required for the visual activity of the human optic nerve in natural light, color rendering and sharpness can be improved. It becomes possible to provide the lighting fixture which can be improved.

1 shows the wavelength distribution of a white light LED
Figure 2 shows the case of simulating the wavelength distribution of the white light LED
3 and 4 show wavelength distributions simulated by a color rendering simulator when LEDs of 492-500 nm wavelength and LEDs of 610-625 nm wavelength are added to a white light LED.
5 is a stand using a white light LED to which the present invention is applied
6 shows the structure of a substrate for applying the present invention to a stand.
FIG. 7 is a view for explaining a structure of fixing the substrate of FIG. 6 to a stand shade. FIG.
Figure 8 shows the wavelength distribution when the present invention is applied
Figure 9 is a perspective view of the incandescent bulb-type LED lamp to which the present invention is applied
Figure 10 is a side view of the incandescent bulb-type LED lamp to which the present invention is applied

As described above, in order to improve the color rendering property of the white light LED having the spectral distribution as shown in FIG. 1, using LEDs of various wavelengths is difficult to manufacture LEDs for each wavelength and is disadvantageous in terms of manufacturing cost and yield. It is desirable to improve color rendering overall by using a white light LED having excellent yield and unit cost as a main light source, and using only a specific wavelength LED which greatly affects color rendering as an auxiliary light source.

On the other hand, in the field of luminaires, the sharpness is important along with the color rendering. To be a desirable lighting device, the color rendering should be improved along with the sharpness.

By the way, according to the research of the present invention, the experimental results obtained by adding the 610-625nm wavelength to the white light LED improves the color rendering index (CRI), especially the high sensitivity of rod cells in the luminaire using the white light LED Adding the 492-500nm wavelength improves the color rendering index (CRI) to almost 92 or more (CRI simulation values are shown to be 94.96 and 96.57 in Figures 3 and 4), and the visual cells increase their overall activity and clarity. It is concluded that is improved.

Referring to FIG. 2, these graphs capture screens simulated in a CRI simulator. In the first drawing, the upper graph shows the wavelength distribution of wavelengths emitted from a white light LED by wavelength, and the lower graph shows wavelengths. The distribution is shown in red, and it can be seen that it has a wavelength distribution similar to the graph in FIG.

In FIG. 3, when the LED (red line) having a peak value at 492-500 nm wavelength and the LED (green line) having a peak value at 610-625 nm wavelength are added to the wavelength distribution (blue line) of the white light LED as shown in the lower graph. The CRI (Ra), which is the color rendering index, was simulated as 94.96.

And, in FIG. 4, unlike FIG. 3, when more LEDs (green) having peak values at 610-625 nm wavelengths are used, CRI (Ra), which is a color rendering index, is simulated to be 96.57.

Here, in the case of luminaires emitting less wavelengths of 492-500nm, the illuminance needs to be increased to higher brightness to improve clarity, which requires higher power consumption, and therefore, luminaires emitting moderate amounts of 492-500nm wavelengths consume less. It is a key wavelength in the present invention in that the same sharpness as in the case of high illuminance can be achieved with power.

Therefore, in the LED luminaire of the present invention, a white light LED is used as a main light source, and an LED having a peak value at a wavelength of 492-500 nm and an LED having a peak value at a wavelength of 610-625 nm are used as an auxiliary light source.

Here, the LED lighting device according to the present invention, mobile light (for example, fluorescent lamps used in many study room or incandescent lamp type puller stand used in Europe and America) and fixed lamps (for example, room and living room, etc. Fluorescent lamp square lamp / round lamp) to be used.

Now, the case in which the present invention is applied to a fluorescent lamp stand will be described with reference to FIGS. 5 to 7.

First, FIG. 5 illustrates the external shape of the fluorescent lamp stand according to the present invention, in which the substrate 4 as shown in FIG. 6 is disposed inside the lamp portion 8, and the white light LEDs 1 are disposed on the substrate 4. ) And LEDs 2 of 492-500 nm wavelength and LEDs 3 of 610-625 nm wavelength are appropriately arranged. At this time, such LEDs (1, 2, 3) can be arranged in a variety of forms, such as alternately arranged in a row unit (in Figure 6 the white light LED (1) is arranged in the center, LEDs of 492-500nm wavelength) (2) and LEDs 3 of 610-625nm wavelength are arranged in one row above and below the periphery), the number of LEDs 2, 3 is the intensity of the light of the total white light LED 1, and each LED 2, In consideration of the light intensity of 3), an appropriate number is used.

Substrate wirings (not shown) for supplying power for driving the LEDs 1, 2, and 3 are formed on the back surface of the substrate 4, and the substrate wirings are connected to the conductive wires 6, by the substrate wiring connecting portion 5, respectively. 7) is connected.

Next, if the substrate 4 is fixed to the stand shade 8 using screws, or the substrate 4 is fixed to the elastic latching structure 9 provided in the stand shade 8 as shown in FIG. The stand shade 8 for the present invention is formed, and the stand shade 8 is extended through the extension member 10 (conductors 6 and 7 pass through therein) and the pedestal 11 as shown in FIG. When combined with the eye protection stand of the present invention is formed.

At this time, the drive device 12 for the LEDs 1, 2, 3 is arranged inside the pedestal 11, and the output of the drive device 12 is connected to the wirings 6,7.

Now, when the user turns on the switch 13 and applies household AC power to the drive device 12 inside the main body, the output of the drive device 12 is led by the wirings 6 and 7 to the LEDs 1, 2, 3. Is supplied.

That is, when the user turns on the switch 13, the LEDs 1, 2, and 3 are all lit, so that the white light LEDs 1 emit light having the wavelength distribution as shown in FIG. 1, and the LEDs 2 The light emitting device emits light having a wavelength of 492-500 nm, and emits light having a wavelength of 610-625 nm from the LEDs 3, thereby completing a lighting apparatus using a white light LED having a wavelength distribution as shown in FIG.

In addition, when the anti-glare filter is additionally installed in the stand shade 8 of FIG. 5, the glare may be prevented.

In addition, while the above-described stand for the tabletop stand as an example of a mobile luminaire, the substrate may be installed in a recessed square lamp / circle lamp installed in a living room or a room which is a fixed luminaire, or a street lamp / security lamp of an outdoor street. .

Next, an incandescent lamp-type LED lighting device for applying the principle of the present invention to a luminaire having an incandescent lamp-type socket will be described with reference to FIGS. 9 and 10.

The incandescent lamp-type LED lighting fixture of the present invention, as shown in Figure 9, 10 because the LED lamp (transparent or semi-transparent protective cap is often installed at the bottom) is coupled to the existing incandescent lamp-type lighting fixtures, as follows: In the following, only the LED lamp for the present invention will be described in detail.

The LED lamp 20 is helically coupled to the incandescent lamp socket (coupling structure) of the incandescent lamp-type lighting fixture by the metallic outer socket 21 to be connected to the AC power supply 220V.

Then, a plurality of LEDs (23, 24, 25) are disposed on the lower end 22 of the LED lamp 20,

In FIG. 9, the white light LED 23 is disposed at the center portion, and the LEDs 24 having the wavelengths of 492-500 nm and the LEDs 25 having the wavelengths of 610-625 nm are disposed at the periphery thereof. Place it.

In addition, as shown in FIG. 10, a driving device 27 for driving the LEDs 23, 24, and 25 is present in the substrate 26 inside the LED lamp 20, and AC power is supplied through the external socket 21. It is supplied to the drive device 27 and the terminals of the LEDs 1, 2, 3 are connected.

At this time, the intensity and number of light of each of the LEDs (23, 24, 25) is appropriately determined in consideration of the number of watts of the LED lamp 20 used, color rendering and sharpness to improve.

Now, after installing by turning the LED lamp 20 into the socket of the incandescent lamp luminaire (not shown) using the external socket 21 of the LED lamp 20 as shown in Figures 9 and 10, the user turned on the power. Then, AC power is supplied to the driving device 27 so that the LEDs 23, 24, and 25 are all lit, so that the white light LEDs 23 emit light having a wavelength distribution as shown in FIG. 24) emits light having a wavelength of 492-500 nm, and the LEDs 25 emit light having a wavelength of 610-625 nm, thereby completing an LED lamp for a white light LED lighting device having a wavelength distribution as shown in FIG.

In addition, in the LED lamp 20 of the present invention in Figures 9 and 10, the LEDs 23, 24, 25 are shown to be attached to the bottom of the LED lamp 20 in close contact, LEDs 23, 24, 25 At least a portion of the) may be provided at each end of the support structure that extends from the lower end, one at each, and at least one LED (23, 24, 25) is provided on the outer peripheral surface of each support structure It is also possible, it may be installed on the outer peripheral surface side of the LED lamp (20).

On the other hand, in the above described as an example of the LED lamp as an incandescent bulb type lamp, the substrate of the LED combination according to the present invention is applied to fluorescent LED lamps, halogen bulb replacement LED lamps, PAR type lamp replacement LED lamps, etc. It is also possible.

In the above description of the preferred embodiment of the present invention, it should be noted that the present invention is not limited to these embodiments, but various modifications can be made without departing from the principles of the present invention.

Claims (5)

In the LED lighting fixture using the white light LED,
White light LEDs (1) which emit light having a first peak in the 440-460 nm wavelength range and a second peak in the 520-600 nm wavelength range as a main light source;
First LEDs 2 emitting light having a third peak value in a wavelength range of about 492-500 nm to improve sharpness as an auxiliary light source;
Second LEDs 3 for emitting color having a fourth peak in the wavelength range of about 610-625 nm to improve color rendering as an auxiliary light source;
A substrate (4) on which the white light LEDs (1), the first LEDs (2), and the second LEDs (3) are disposed;
A driving device (12) for driving the white light LEDs (1), the first LEDs (2) and the second LEDs (3);
LED lighting device using a white light LED, characterized in that it comprises a wiring (6, 7) connecting between the substrate (4) and the drive device (12). The method of claim 1,
LED lighting fixture using a white light LED, characterized in that the lighting fixture is a mobile luminaire. The method of claim 2,
LED lighting fixture using a white light LED, characterized in that the anti-glare filter is further installed on the lighting fixture. The method of claim 1,
LED lighting fixture using a white light LED, characterized in that the lighting fixture is a fixed luminaire. In the LED lamp using the white light LED,
An external socket 21 for receiving AC power;
White light LEDs (23) disposed at the bottom of the LED lamp and emitting light having a first peak in the 440-460 nm wavelength range and a second peak in the 520-600 nm wavelength range as a main light source;
First LEDs 24 disposed at a lower end of the LED lamp and emitting light having a third peak value in a wavelength range of about 492-500 nm to improve clarity as an auxiliary light source;
Second LEDs 25 disposed at a lower end of the LED lamp and emitting light having a fourth peak in a wavelength range of about 610-625 nm to improve color rendering as an auxiliary light source;
A driving device 27 for driving the white light LEDs 23, the first LEDs 24, and the second LEDs 25;
A substrate on which the white light LEDs 23, the terminals of the first LEDs 24, the second LEDs 25, and the driving device 27 are disposed and receive AC power from the external socket 21. An LED lamp using a white light LED, characterized by comprising (26).

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