DE202012101054U1 - A heat dissipation device for lamps - Google Patents

Abstract

A heat dissipation device for lamps, comprising: a glass lampshade (1), a first opening (11) being formed on the top of this glass lampshade (1) and a second opening (12) on the underside of the glass lampshade (1); the diameter of the first opening (11) is less than the diameter of the second opening (12); an annular groove (121) having a base is formed between the first opening (11) and the second opening (12), a light source (3) being mounted on the base of the annular groove (121); a glass frame (2) which is fastened to the second opening (12), the light source (3) being covered with this glass frame (2); and the heat from the light source (3) is therefore quickly released into the air, since the glass lampshade (1) and the glass holder (2) have a high thermal conductivity, and the light source (3) is not impaired in the long term by the waste heat .

Description

Technical area

The present invention relates to a heat dissipation device, in particular a heat dissipation device for lamps.

State of the art

With the development of high-efficiency and high-power LEDs, it became possible to use LEDs for lamps and lighting. Replacement bulbs have been manufactured as well as dedicated fixtures and LED bulbs. LEDs are used as street lights and as other lights in different colors in buildings. However, the efficiency of the light emission of the LED lamp is slightly affected by the waste heat, and especially under high voltage of the electric current for a longer period, the power of the light emission in other colors becomes unstable. In addition, the electrical components are easily damaged in a high temperature environment. For these reasons, the creation of an efficient heat sink for an LED lamp has become a major issue in this field.

The heat dissipation devices of the prior art are with several thermally conductive ribs 5 provided around a transparent part 6 the lamp are formed. The thermally conductive ribs 5 are radially aligned on the lamp, so that the waste heat easily to the thermally conductive ribs 5 led and then released into the air. The thermally conductive ribs 5 For the contact of the lamp with the air on a large contact surface, wherein each of the thermally conductive ribs 5 is constructed of materials with a high thermal conductivity, z. B. of copper, aluminum and aluminum alloys. With these materials, the waste heat can quickly pass over the thermally conductive ribs 5 be released into the air. Further, to increase the contact area between the lamp and the air, the thermally conductive fins can be bent.

Unfortunately, the cost of copper, aluminum and aluminum alloy are getting day by day higher, so the cost of producing the thermally conductive fins 5 gets too high. In addition, each of the thermally conductive ribs 5 each have their own size, so that the contact surface due to the number of thermally conductive ribs 5 and the thickness of which can not be fully increased on the lamp. Making a bent and thermally conductive rib 5 with a fixed structure proves to be difficult in an assembly line.

Object of the invention

The main object of the present utility model is to provide an improved lamp heat dissipation device.

In order to achieve the above object, a glass lampshade for lamps according to the present invention is constructed of a glass lampshade, on the upper side of which a first opening is formed, while the underside of the glass lampshade is provided with a second opening. The diameter of the first opening is less than the diameter of the second opening. An annular groove having a base is formed between the first opening and the second opening with a light source mounted to the base of the annular groove. A glass frame is mounted to the second opening to shield the light source so that the waste heat generated by the light source is quickly released into the air thanks to the high thermal conductivity of both the glass lamp shade and the glass socket. Therefore, the waste heat is not affected by the duration of the light source.

The glass lampshade has on its periphery at least one vent hole and at least one second vent hole, wherein the first vent hole is formed close to the first opening and the second vent hole close to the second opening.

The glass lampshade is provided on its periphery with at least one first vent hole or with at least one second vent hole.

The base of the annular groove is provided with at least a third vent hole, which is close to the light source.

Brief description of the drawings

The drawings show:

1 shows an exploded view of a heat dissipation device for lamps according to the present utility model;

2 shows a cross-sectional view of the heat dissipation device for lamps according to the present utility model;

3 shows a perspective view of the heat dissipation device for lamps with a power connector;

4 shows an exploded view of a heat dissipation device for lamps with the two first, second and third ventilation holes;

5 shows an exploded view of a heat dissipation device for lamps with the eight first, second and third ventilation holes;

6 shows a Querschnttansicht the in the 4 embodiment shown; and

7 shows a perspective view of the embodiment of the prior art.

Ways to carry out the invention

As in the 1 - 3 is a heat dissipation device for lamps according to the present invention from a glass lampshade 1 and from a glass version 2 built up. The glass lampshade 1 consists of a material with a high thermal conductivity, eg. As copper, aluminum and aluminum alloys. The shape of the glass lampshade 1 is very similar to that of a flower pot. On the top of the glass lampshade 1 is a first opening 11 formed while on the bottom of the glass lampshade 1 a second opening 12 is formed. The diameter of the first opening 11 is less than the diameter of the second opening 12 , Between the first opening 11 and the second opening 12 is an annular groove 121 formed with a base. At this base of the annular groove 121 is a light source 3 attached.

The glass version 2 is at the second opening 12 attached. The glass version 2 is made of a transparent material with a high thermal conductivity, z. B. made of glass. With the glass frame 2 becomes the light source 3 covered. As a light source 3 a light emitting diode is used. The of the light source 3 emitted light rays are used to illuminate the immediate environment from the glass frame 2 broadcast. A power connector 4 is at the first opening 11 assembled. The light source 3 is electrical with the power connector 4 connected.

In this arrangement, the waste heat from the light source 3 quickly released into the air, as the glass lampshade 1 and the glass version 2 both have a high thermal conductivity. The waste heat during use in the long run is not from the light source 3 affected.

As in the 1 - 2 shown is the glass lampshade 1 continue with a first ventilation hole 13 and with at least one second vent hole 13 provided on the periphery of the glass lampshade 1 are formed. This is the first vent hole 13 close to the first opening 11 shaped while the second vent hole 14 close to the second opening 12 is shaped. The first ventilation hole 13 and the second vent hole 14 are perpendicular to the periphery of the glass lampshade 1 aligned. Furthermore, the base of the annular groove 121 above with at least a third ventilation hole 122 Mistake. The third ventilation hole 122 is close to the light source 3 educated. The air of the waste heat is depending on the location of the first ventilation hole 13 , second ventilation hole 14 and the third vent hole 122 up into the third ventilation hole 122 passed and through the first vent hole 13 discharged to the air, with the cooler air from the outside through the second vent hole 14 in the glass lampshade 1 and in the glass version 2 flows in to form the heat convection.

Like in the 4 shown is the glass lampshade 1 for heat convection with two first ventilation holes 13 , two second ventilation holes 14 and with two third ventilation holes 122 Mistake.

Like in the 5 shown is the glass lampshade 1 for heat convection with eight first ventilation holes 1 , eight second ventilation holes 14 and with eight third ventilation holes 122 Mistake.

Thus, the waste heat from the light source 3 not only through the heat conduction through the glass lampshade 1 and the glass version 2 but also by the heat convection through the first vent hole 13 , the second ventilation hole 14 and through the third ventilation hole 122 released into the air.

LIST OF REFERENCE NUMBERS

1

Glass lampshade

11

First opening

12

Second opening

13

First ventilation hole

14

Second ventilation hole

121

Ring-shaped groove

122

Third ventilation hole

2

glass Fitting

3

light source

4

Power connector

5

heat conduction

6

Transparent part

Claims (6)

A heat dissipation device for lamps, comprising: a glass lampshade ( 1 ), wherein on the top of this glass lampshade ( 1 ) with a first opening ( 11 ) and on the underside of the glass lampshade ( 1 ) a second opening ( 12 ) are formed; the diameter of the first opening ( 11 ) is less than the diameter of the second opening ( 12 ); an annular groove ( 121 ) with a base is between the first opening ( 11 ) and the second opening ( 12 ), wherein at the base of the annular groove ( 121 ) a light source ( 3 ) is mounted; a glass version ( 2 ) located at the second opening ( 12 ), the light source ( 3 ) with this glass version ( 2 ) is covered; and the heat from the light source ( 3 ) is therefore released quickly into the air, since the glass lampshade ( 1 ) and the glass frame ( 2 ) have a high thermal conductivity, and the light source ( 3 ) is not affected in the long run by the waste heat. The heat dissipation device for lamps according to claim 1, characterized in that the glass lampshade ( 1 ) with at least one first ventilation hole ( 13 ) and at least one second vent hole ( 14 ) is provided on the periphery, wherein the first vent hole ( 13 ) close to the first opening ( 11 ) and the second ventilation hole ( 14 ) close to the second opening ( 12 ) is located. The heat dissipation device for lamps according to claim 1 or 2, characterized in that the glass lampshade ( 1 ) with at least one first ventilation hole ( 13 ) or with at least one second ventilation hole ( 14 ) located on the periphery of the glass lampshade ( 1 ) is formed. The heat dissipation device for lamps according to one of the preceding claims, characterized in that the base of the annular groove ( 121 ) with at least one third ventilation hole ( 122 ) is provided. The heat dissipation device for lamps according to one of the preceding claims, characterized in that the third ventilation hole ( 122 ) close to the light source ( 3 ) is located. The heat dissipation device for lamps according to one of the preceding claims, characterized in that the glass lampshade ( 1 ) on the periphery with several first ventilation holes ( 13 ) and with several second ventilation holes ( 14 ), whereby the first ventilation holes ( 13 ) close to the first opening ( 11 ) and the second ventilation holes ( 14 ) close to the second opening ( 12 ) are located; the base of the annular groove ( 121 ) and close to the light source ( 3 ) with several third ventilation holes ( 122 ) is provided.

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