KR101622075B1 - Bulb type illuminating apparatus using led - Google Patents

Abstract

The present invention relates to a bulb type illuminating apparatus using an LED. The bulb type illuminating apparatus using an LED according to the present invention includes a bulb type illuminating body; a light source part which has at least one LED and is arranged on the front surface of the bulb type illuminating body; and an aspheric lens which comprises a first refraction part which refracts illuminating light provided to the center of an incident surface from the light source part and disperses the light, and a second refraction part which refracts illuminating light provided to the peripheral part of the incident surface in a lateral direction, and is arranged on the front surface of the illuminating body. So, heat generated in the illuminating apparatus can be effectively radiated.

Description

TECHNICAL FIELD [0001] The present invention relates to a bulb type illumination device using an LED,

[0001] The present invention relates to a bulb-type lighting apparatus using LED, and more particularly, to a bulb-type lighting apparatus using an LED, which is capable of minimizing the phenomenon of center-of- And a lighting device.

The light emitting diode (LED) is smaller in size than a conventional light source, has a long life span, and uses the characteristics of a compound semiconductor to directly convert electric energy into light energy, Various lighting apparatuses using such LED as a light source have been developed.

However, the LED has a problem in that it is used as a general lighting device because it is very glare due to the straight-line characteristic that the light is 'glowing' at one point and is used for special lighting of the exhibition hall or the headlight of a vehicle,

That is, since the illumination lamp using the LED is emitted only in the forward direction without being emitted in all directions at 360 degrees, the light distribution characteristic differs greatly from the conventional incandescent lamp. For example, a general LED bulb emits the largest amount of light in the forward 0 degree direction, and as the angle increases, the amount of light emission decreases and becomes almost zero at about ± 90 degrees. On the other hand, in general incandescent bulbs, the emission amount is kept almost constant without decreasing from about 0 to about 130 degrees. Accordingly, the full-width at half-maximum (FWHM) of the illumination angle of the LED bulb is about 130 degrees, whereas the half-width of the general illumination angle of the incandescent bulb is about 260 degrees. This difference arises because the filament used in a typical incandescent lamp emits light in all directions 360 degrees, whereas the LED emits light in about 120 degrees in the forward direction. Therefore, when the LED is used in an existing lighting device, it is greatly different from the conventional light distribution or lighting feeling familiar to the user, so that natural light can not be produced as a living illumination.

In addition, in order to prevent glare due to the LED, a plurality of filters for diffusing the illumination light may be provided. In this case, however, the illumination light emitted from the LED is absorbed by the diffusion filter.

In addition, although the LED has a very long lifetime and relatively low power consumption, it can be deteriorated by the heat generated by the LED itself to shorten its service life. Accordingly, conventional LED bulbs are designed to radiate heat by adding radiating fins higher than a certain height to the outside in order to emit heat. However, there is a problem that the appearance of the LED illumination becomes complicated and dirty by the heat dissipation fin.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the prior art as described above and to solve the problems of the related art by providing a method of reducing the glare phenomenon by minimizing the light amount center biasing phenomenon of the LED, Thereby providing a spherical illumination device.

Another object of the present invention is to provide a lamp-type lighting apparatus using an LED capable of effectively emitting heat generated inside the lighting apparatus.

According to an aspect of the present invention, there is provided a light source unit including: a light source unit including a light source unit, a light source unit having at least one LED and disposed on a front surface of the light source unit; And a second refracting portion for refracting and dispersing illumination light provided toward the periphery of the incident surface in a lateral direction to form a second refracting portion for refracting and dispersing the illumination light provided toward the center of the incident surface from the light source portion, And an aspheric lens disposed on the front surface of the main body.

Here, it is preferable that a plurality of the LEDs are provided and spaced apart in the circumferential direction from the front center of the lighting main body.

In addition, the LED preferably includes at least one of a first LED that provides a warm white-based illumination light, a second LED that provides a cool-white-based illumination light, and a third LED that provides an RGB color illumination light.

The power supply unit may further include a power supply unit disposed in the interior of the lighting unit to convert an external power source into a constant current and a constant voltage and supply the power to the light source unit.

The present invention provides a wireless communication device, comprising: a wireless receiver for wirelessly receiving a control signal for lighting control; And a controller for controlling a current supplied to the light source according to a control signal received through the wireless receiver.

It is preferable that the first refracting portion comprises a circular concave lens, and the second refracting portion comprises a ring-shaped convex lens.

In addition, it is preferable that the first refracting portion has a smaller diameter than the circumference where the LED of the light source portion is disposed.

The second refracting portion may have a relatively larger diameter than the circumference where the LED of the light source portion is disposed.

The aspherical lens is preferably made of a transparent material.

The heat sink may further include a heat sink disposed on a side surface of the illuminating body to absorb heat generated from the light source and emit the heat to the outside.

The heat sink may include a heat absorbing cover which is in close contact with the outer surface of the lighting body, a heat radiating cover which is spaced apart from the heat absorbing cover by a predetermined distance, and a plurality of connecting pieces connecting the outer circumferential surface of the heat absorbing cover and the inner circumferential surface of the heat radiating cover .

It is preferable that the concave and convex portions are formed along the longitudinal direction on the outer circumferential surface of the illumination body and the inner circumferential surface of the heat absorbing cover and are engaged with each other.

In addition, it is preferable that at least one side of the space between the heat absorbing cover and the heat radiation cover is opened.

The space between the heat-absorbing cover and the heat-radiating cover is opened at both sides, and a space between the aspherical lens and the front portion of the lighting body is communicated with the spacing space.

According to the present invention, there is provided a bulb-type lighting apparatus using an LED capable of minimizing the phenomenon of center-of-gravity of light intensity of the LED, thereby reducing the glare phenomenon and minimizing the light loss and improving the light efficiency.

Further, a spherical illumination device using an LED capable of effectively emitting heat generated in the illumination device is provided.

1 is a perspective view of a spherical illumination device using LED of the present invention,
2 is an exploded perspective view of a spherical illumination device using LED of the present invention,
3 is a cross-sectional view taken along the line A-A 'in Fig. 1,
4 is a sectional view taken along the line B-B 'in Fig. 3,
5 is a view showing the optical path of an aspherical lens of a spherical illumination device using the LED of the present invention,
6 is a view showing a heat discharge path of a heat sink of a spherical lighting device using the LED of the present invention.

Prior to the description, components having the same configuration are denoted by the same reference numerals as those in the first embodiment. In other embodiments, configurations different from those of the first embodiment will be described do.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A lighting fixture using an LED according to a first embodiment of the present invention will now be described in detail with reference to the accompanying drawings.

1 is a perspective view of a spherical illumination device using the LED of the present invention, and FIG. 2 is an exploded perspective view of a spherical illumination device using the LED of the present invention.

The light emitting device using the LED of the present invention as shown in the figure includes an illumination body 110, a light source 120, an aspherical lens 130, and a heat sink 140.

The lighting main body 110 includes a cylindrical receiving portion 112 having a receiving space therein and a power terminal portion 112 formed at the rear end of the receiving portion 112 to be coupled to the bulb socket and electrically connected to the bulb socket, (111).

The light source unit 120 includes a substrate 121 disposed on the front surface of the spherical illumination main body 110 and a plurality of LEDs 122 disposed on the substrate 121 in the circumferential direction. The plurality of LEDs 122 includes a first LED 122a for providing illumination light of a warm white color system, a second LED 122b for providing illumination light of a cool white system, a third LED 122b ), And when two or more kinds are applied, it is preferable to arrange them alternately.

A power supply unit 150 for converting a power supplied from the outside into a constant current and a constant voltage and supplying the power to the light source unit 120 is disposed in the cylindrical receiving unit 112 of the illumination main body 110, A controller 121 for controlling the current supplied to the light source unit 120 according to a control signal received through the wireless receiver unit 160, (170).

The aspherical lens 130 is formed of a transparent material having excellent light transmittance such as optical glass or polycarbonate and disposed on the front surface of the illumination body 110. The aspherical lens 130 irradiates illumination light provided toward the center of the incident surface from the light source 120 A second refracting part 132 for refracting and dispersing the illumination light provided toward the rim of the incident surface in the lateral direction and a second refracting part 132 for refracting and dispersing the illumination light toward the rim of the incident surface, And a transparent portion 133 that extends in the vertical direction and provides illumination light provided toward the side surface in the lateral direction. The first refracting part 131 is formed of a circular concave lens having a diameter smaller than that of the circumference where the LED 122 of the light source part 120 is disposed, And a ring-shaped convex lens having a relatively larger diameter than the circumference where the LED 122 of the light source unit 120 is disposed.

The heat sink 140 is made of a material having a high thermal conductivity such as aluminum and absorbs heat generated from the light source unit 120 and the power supply unit 150 and discharges the heat to the outside. A heat dissipation cover 143 disposed at a predetermined distance from the heat absorbing cover 141 and an inner circumferential surface of the heat dissipation cover 143 and an outer circumferential surface of the heat absorbing cover 141, And a plurality of connecting pieces 144 for connecting the heat absorbing cover 141 and the heat dissipating cover 143. The space S between the heat absorbing cover 141 and the heat dissipating cover 143 is opened at an upper end and a lower end, respectively. In addition, the outer circumferential surface of the illumination body 110 and the inner circumferential surface of the heat absorbing cover 141 are configured so that the concave-convex portions 113 and 142 for increasing the surface area extend along the longitudinal direction and are engaged with each other.

Hereinafter, the operation of the first embodiment of the spherical illumination device using the LED will be described.

3 is a cross-sectional view taken along the line A-A 'in Fig. 1, Fig. 4 is a sectional view taken along the line B-B' in Fig. 3, and Fig. 5 is a cross- And FIG. 6 is a view showing a heat discharge path of the heat sink of the compact lighting apparatus using the LED of the present invention.

3 and 4, the heat sink 140 is inserted into the heat absorbing cover 141 of the heat sink 140 such that the cylindrical receiving portion 112 of the lighting body 110 is inserted into the heat sink 140, Side end portion of the illumination body 110 is supported by the illumination main body 110. At this time, the heat absorbing cover 141 and the cylindrical receiving portion 112 are tightly coupled to each other with the concave and convex portions 113 and 142 formed on the surfaces facing each other.

The substrate 121 of the light source unit 120 is fixed to the entire surface of the cylindrical receiving portion 112 of the illumination main body 110 while being supported by the other end of the heat absorbing cover 141 of the heat sink 140, The state of engagement between the sink 140 and the illumination main body 110 is maintained.

The aspherical lens 130 is coupled to the heat radiating cover 143 of the heat sink 140 by the outer edge of one end portion of the aspherical lens 130 while the light source unit 120 is being wrapped.

The power supply unit 150 accommodated inside the cylindrical accommodating unit 112 of the illumination main body 110 is electrically connected to the power terminal unit 111 formed at the rear end of the illumination main body 110 to receive AC power from the outside, Converts the AC power to a constant-voltage constant-current DC power, and outputs it to the LED 122.

The plurality of LEDs 122 provided on the substrate 121 of the light source unit 120 are disposed on the circumference of a circle corresponding to the heat absorbing cover 141 of the heat sink 140, 120 toward the incident surface of the aspherical lens 130.

As shown in FIG. 5, among the illumination light provided toward the incident surface of the aspherical lens 130, the illumination light provided toward the center of the incident surface is refracted by the first refracting portion 131 having a concave lens shape, Since the lens 130 is dispersed toward the periphery from the center of the exit surface of the lens 130, it is possible to reduce the glare caused by the center of gravity of the light amount.

The illumination light provided toward the center outward of the incident surface is refracted by the second refracting portion 132 having a convex lens shape and condensed at an adjacent position from the exit surface of the aspherical lens 130, And is dispersed toward a direction inclined at about 45 degrees with respect to the center.

The illumination light provided toward the side surface of the incident surface is directed in the direction of approximately 90 degrees perpendicular to the light projecting portion 133 through the light projecting portion 133 extending in the vertical direction at the outer edge of the second refracting portion 132 ≪ / RTI >

Since the illumination light provided from the light source unit 120 is refracted and dispersed through the transparent aspheric lens 130, the light loss can be minimized and the luminous efficacy can be improved.

In particular, the second refracting portion 132 composed of a convex lens refracts the illumination light provided from the LED 122 in the lateral direction so as to be converged at a position adjacent to the emitting surface, and then is dispersed again so that the appearance of the lens is not harmed Thereby providing an effect of dispersing light. The refraction angle and the condensing position by the convex lens as described above can be appropriately adjusted by changing the curvature of the convex lens according to the characteristics of the illumination light.

The half width of the illumination light incident on the incident surface of the aspherical lens 130 through the light source unit 120 is approximately 120 degrees while the half width of the illumination light provided through the exit surface of the aspherical lens 130 is approximately 200 degrees It can provide an illumination atmosphere similar to that of an existing incandescent lamp. In this process, the light is prevented from concentrating to one side without applying the diffusion filter, so that the glare due to the illumination of the LED 122 can be prevented, and the light efficiency can be improved.

The LED 122 of the light source unit 120 includes a first LED 122a for providing illumination light of a warm white type, a second LED 122b for providing illumination light of a cool white type, LEDs 122c, so that various types of illumination colors can be provided.

In particular, the wireless receiving unit 160 provided on the substrate 121 of the light source unit 120 wirelessly receives a control signal input from an external device such as a remote controller, and the controller 170, according to the received control signal, The user can adjust the color and brightness of the illumination light as well as on / off of the illumination by adjusting the supply amount and the supply ratio of the current supplied to the first to third LEDs 122a, 122b, have.

6, the heat generated by the power supply unit 150 and the heat generated by the LED 122 of the light source unit 120 are transmitted to the outside through the heat sink 140 provided outside the cylindrical receiving unit 112 Exchanged and cooled.

The heat absorbing cover 141 of the heat sink 140 has a structure in which the inner circumferential surface is in close contact with the outer surface of the cylindrical receiving portion 112 of the illumination body 110 and the heat generated from the power supply portion 150 accommodated inside the cylindrical receiving portion 112 Lt; / RTI >

At this time, a large number of concave-convex portions 113 and 142 are formed on the surfaces of the cylindrical receiving portion 112 and the endothermic cover 141 facing each other, thereby increasing the surface area for heat exchange. ) Is improved (see Fig. 4)

The heat generated by the LED 122 of the light source 120 is absorbed by the lower end of the heat absorbing cover 141 of the heat sink 140 and the heat absorbed by the heat sink 140 is absorbed by the outer surface of the heat absorbing cover 141 To the heat radiating cover 143 side through a plurality of connecting pieces 144 disposed radially in the heat radiating cover 143 and exchanges heat with the outside air.

Particularly, the space S between the heat absorbing cover 141 and the heat dissipating cover 143 spaced apart by the connecting piece 144 has an upper end and a lower end opened, The heat released to the spacing space S is discharged through the connecting piece 144 to the heat radiating cover 143. The heat radiated to the spacing space S escapes to the outside through the opening at the upper end by the convection phenomenon, The heat absorbed by the cover 141 can be quickly cooled. That is, by arranging the heat dissipation cover 143 outside the plurality of radially arranged connecting pieces 144, it is possible to provide a beautiful appearance without deteriorating the heat dissipation performance.

Also, the space on the front surface of the illumination body 110 closed with the aspherical lens 130 is also communicated with each other through the lower end opening of the spacing space S. The heat transferred to the space between the aspherical lens 130 and the front surface of the illumination main body 110 can be escaped to the outside through the spaced space S so that the life of the LED 122 is prevented from being shortened by heat can do.

The scope of the present invention is not limited to the above-described embodiments, but may be embodied in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

110: illumination body, 111: power supply terminal, 112: cylindrical receptacle,
113: concave / convex portion, 120: light source portion, 121:
122: LED, 122a: first LED, 122b: second LED,
122c: third LED, 130: aspheric lens, 131: first refraction portion,
132: second refracting portion, 133: transparent portion, 140: heat sink,
141: heat absorbing cover, 142: concave / convex portion, 143: heat radiating cover,
144: connecting piece, 150: power supply part, 160: wireless receiving part,
170: Controller

Claims (14)

A spherical illumination body;
A light source unit having a plurality of LEDs disposed circumferentially spaced apart from a center of a front surface of the globular illumination body; And
A first refracting portion disposed on the front surface of the illuminating main body for refracting and dispersing the illumination light provided toward the center of the incident surface from the light source portion and a second refracting portion for refracting and distributing the illumination light provided toward the periphery of the incident surface in the lateral direction And an aspheric lens on which a second refracting portion is disposed to surround the first refracting portion,
Wherein the first refracting portion is made of a concave lens having a diameter smaller than the circumference where the LED of the light source portion is disposed and the second refracting portion is made of a convex lens having a diameter larger than a circumference where the LED of the light source portion is disposed Wherein the light source is a light source. delete The method according to claim 1,
Wherein the LED comprises at least one of a first LED that provides a warm white-based illumination light, a second LED that provides a cool-white-based illumination light, and a third LED that provides RGB color illumination light. Whole spherical lighting device. The method according to claim 1,
And a power supply unit disposed in the interior of the lighting unit to convert a power supplied from the outside into a constant current and a constant voltage and to supply the constant current and the constant voltage to the light source unit. 5. The method of claim 4,
A wireless receiver for wirelessly receiving a control signal for lighting control; And
And a controller for controlling a current supplied to the light source according to a control signal received through the wireless receiver. delete delete delete The method according to claim 1,
Wherein the aspheric lens is made of a transparent material. 10. The method according to any one of claims 1 to 9,
And a heat sink disposed on a side surface of the illumination body to absorb heat generated from the light source and emit the heat to the outside. 11. The method of claim 10,
Wherein the heat sink includes an endothermic cover which is in close contact with an outer surface of the lighting body, a heat radiating cover which is spaced apart from the heat absorbing cover by a predetermined distance, and a plurality of connecting pieces connecting the outer circumferential surface of the heat absorbing cover and the inner circumferential surface of the heat radiating cover Lt; / RTI > 12. The method of claim 11,
Wherein the concave and convex portions are formed along the longitudinal direction on the outer circumferential surface of the lighting body and the inner circumferential surface of the heat absorbing cover to engage with each other. 12. The method of claim 11,
Wherein at least one side of the spacing space between the heat absorbing cover and the heat radiation cover is opened. 14. The method of claim 13,
Wherein the spacing space between the heat absorbing cover and the heat radiation cover is opened at both sides and a space between the aspherical lens and the front portion of the lighting body is communicated with the spacing space.

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