DE102012100005B4 - LIGHTING BODY WITH LOW INFLUENCE THROUGH HEAT - Google Patents

Abstract

A low heat impact lighting fixture, comprising: a reflector shield (1) having an upper opening (11) at one end and a lower opening (12) at the other end; a lens (3) mounted over the upper opening (11); a reflector shield back (13) formed between the upper opening (11) and the lower opening (12) of the reflector shield (1); a reflector chamber (14) between the upper opening (11), lower opening (12) and the reflector shield back (13), and at least one slot opening (15) formed along the reflector shield back (13) along; and an aluminum base (2) mounted on the lower opening (12); at least one heat-dissipating tube (21) extending from a periphery of the aluminum base (2), said heat-dissipating tube (21) being aligned with the slot opening (15); a light source (22) mounted on the aluminum base (2) and movable in the reflector chamber (14), and the heat dissipation tube (21) is made of a highly thermally conductive material; said aluminum base (2) being movable toward and away from said upper opening (11), respectively, said heat sink tube (21) being respectively moved up and down the movement of said aluminum base (2) to contact said light source (22) the aluminum base (2) for diffusing or focusing the light beams to the lens (3) and to move away from it.

Description

Technical area

The present invention relates to a lighting fixture, in particular a lighting fixture with low influence by waste heat.

State of the art

WO 2010/069159 A1 discloses an LED reflector lamp with a control circuit. At least two LED light sources, each mounted on a light source plate, are controlled by the control circuitry. The light source plates are thermally conductively connected to at least one heat-conducting plate. A reflector shell is formed with a formed on the underside of the reflector shell reflector inner surface and an opening through the edge of the reflector inner surface. A groove is formed on the underside of the reflector shell. In a heat sink, a cavity is provided. The light source plates are inserted into the groove on the underside of the reflector shell so that the LED light sources ( 60 ) are parallel to the vertical center axis of the reflector shell.

US 2010/177521 A1 discloses an LED lamp having a metal housing, a heat pipe and an LED. The metal housing has an outer surface, an inner surface, a bottom, and an opening defined by an inner edge. The heat pipe engages between the inner surface, the bottom and the inner edge of the metal housing. The LED is attached to the bottom portion of the heat pipe. The heat pipe quickly transfers heat from the LED to the metal housing, which then gives off heat to the environment. The heat pipe makes effective heat transport possible and allows the use of high power LEDs or multiple LEDs in a luminaire.

US 2008/0247177 A1 discloses a lighting device with a light source, a housing for receiving the light source and a heat-emitting element. The heat-dissipating member has a heat transfer section and a heat-dissipating section, and is guided by the housing. The heat transfer section is attached to the light source and the heat dissipation section is located outside the housing. A sealing member seals a gap between the heat-dissipating member and the housing.

EP 1 357 335 A2 discloses a lighting device having a light emitting unit, a heat dissipation unit for dissipating heat generated during the light mission, and a heat transfer unit. The heat transfer unit consists of a heat pipe held by the heat dissipation unit for transferring the heat. The heat transfer unit serves as an arrangement member for arranging the light-emitting unit. The heat pipe has a ring-like shape, and the heat dissipation unit has a heat dissipation layer with ceramics.

EP 2 360 430 A1 discloses a lighting device with a thermally conductive housing. A light source part is accommodated with a light emitting element as a light source in the housing. Between a inner wall of the housing and the light source section, a spacer element is arranged. An element accommodating space is located between the spacer and the inner wall of the housing. A heat transfer device thermally connects the light source section and the inner wall of the housing through the element receiving space. The heat generated in the light-emitting element is dissipated by the heat transfer device.

A lighting fixture according to the prior art is composed of a reflector shield and an aluminum base. The reflector shield is provided with an upper opening and a lower opening. Between the upper opening and the lower opening of the reflector shield a reflector shield back is formed. A lens is mounted above the upper opening. The aluminum base is mounted on the lower opening. The aluminum base can be moved to and from the lower opening. The size of the aluminum base is less than the diameter of the lower opening so that the aluminum base can be moved through this lower opening. On the aluminum base, a light source is mounted, which is aligned with the lens, so as to move the light source in accordance with the movement of the aluminum base away from the lens or to the lens. With this structure, when the light source is moved away from the lens and down to the bottom of the reflector shield, light rays reflected from the reflector shield are refracted by the lens, after which these light beams are radiated outward from the lens and collimated with the reflector shield and the lens. When moving the light source to the lens until the light source reaches the upper side of the reflector shield, the light rays emitted from the light source are refracted only by the lens. The light rays are therefore radiated through the lens to the outside and scattered by the lens.

Recently, LED light sources have been increasingly used for lighting fixtures. The efficiency of the light emission of the LED lighting fixture is easily affected by heat, especially at higher power for a long time, resulting in unstable radiation of the colorful light beams and leads to higher color temperatures. The aluminum base plays an important role in dissipating the waste heat from the prior art lighting sources with LED light sources. However, the structure of the aluminum base of the lighting fixture according to the prior art still has two disadvantages described below:
First, since the size of the aluminum base is restricted to a size smaller than the diameter of the lower opening, the heat dissipation area of the aluminum base is not large enough to sufficiently dissipate waste heat from the light source.

Secondly, if the manufacturer increases the size of the aluminum base, the movement space of the light source is restricted by the interaction between the aluminum base and the reflector shield, which affects the focusing and scattering of the light beams.

Object of the invention

It is the object of the present invention to provide an improved lighting fixture.

This object is achieved by a lighting fixture with less influence by waste heat from a reflector shield with an upper opening at one end and a lower opening at the other end, with a lens attached over the upper opening, a reflector shield back between the upper opening and the formed bottom opening of the reflector shield, formed between the upper opening, the lower opening and the reflector shield back a reflector chamber, at least formed a slot opening of the reflector shield back along and an aluminum base is mounted on the lower opening; a heat-dissipating tube extending from the periphery of the aluminum base, said heat-dissipating tube being aligned with the slot opening; a light source, which is mounted on top of the aluminum base and movable in the reflector chamber and the heat dissipation tube consists of a highly thermally conductive material. The size of the aluminum base is less than the diameter of the lower opening. The number of Wärmeableitröhrchen corresponds to that of the slot openings, so that a slot opening corresponds to a Wärmeableitröhrchen, two slot openings two each heat sink and four slot openings four heat dissipation tubes on the reflector shield. The number of slit openings may also be higher than that of the heat-dissipating tubes. At least one spiral slot opening formed in the reflector shield back is formed from the lower opening to the upper opening. The heat sink at the aluminum base in the reflector chamber extends horizontally away from the aluminum base at a respective conforming distance, after which the heat sink is bent at a different respectively conforming distance from the bottom of the reflector chamber.

With this structure, the aluminum base can be moved toward and away from the upper opening, with the heat-dissipation tube being moved up or down in accordance with movement of the aluminum base in the slot opening, to move the light source to diffuse or focus the light rays toward and away from the lens to move.

Brief description of the drawings

The drawings show:

1 shows a perspective view of a lighting fixture according to the invention with less influence by waste heat;

2 Fig. 12 is a perspective view showing an aluminum base and a heat dissipation tube to be moved toward a light-emitting opening;

3 shows a cross-sectional view of the section AA in the 1 along which represents a plurality of light beams to be focused;

4 shows a cross-sectional view of the section BB in the 2 along, which is to be scattered light rays;

5 shows a perspective view illustrating the second embodiment of the present invention;

6 Fig. 12 is a perspective view illustrating the third embodiment of the present invention;

7 Fig. 12 is a perspective view illustrating the fourth embodiment of the present invention;

8th Fig. 12 is a perspective view illustrating the fifth embodiment of the present invention; and

9 - 11 FIG. 3 shows three diagrams as an example of the embodiments of the lighting fixtures corresponding to the first embodiment, the second embodiment, and the third embodiment, respectively.

Ways to carry out the invention

As in the 1 - 4 shown is a lighting fixture with less influence Waste heat according to the present invention from a reflector shield 1 and an aluminum base 2 built up. The reflector shield 1 is at one end for unimpeded emission of the light with an upper opening 11 and at the other end with a lower opening 12 Mistake. Between the upper opening 11 and the lower opening 12 of the reflector shield 1 is a reflector shield back 13 shaped. A reflector chamber 14 is between the upper opening 11 , the lower opening 12 and the reflector shield back 13 educated. At least one slot opening 15 is the reflector shield back 13 along, with one end of this slot opening 15 with the lower opening 12 connected is. A lens 3 is on the top opening 11 attached. The aluminum base 2 is at the bottom opening 12 attached. From the periphery of the aluminum base 2 at least one heat dissipation tube extends 21 after the slot opening 15 is aligned, with the number of mounted heat sinks 21 that of the slot openings 15 equivalent. On top of the aluminum base 2 is one in the reflector chamber 14 moving light source 22 assembled. This light source 22 is after the lens 3 aligned. The heat-dissipation tube 21 consists of a highly thermally conductive material.

As in the 1 - 2 shown is the aluminum base 2 smaller in size than the lower opening 12 to this aluminum base 2 upwards to the upper opening 11 or down and away from her and through the lower opening 12 to move. The width of the slot opening 15 is greater than the diameter of the cross-section of the Wärmeableitröhrchens 21 to this heat-dissipation tube 21 the slot opening 15 along and along with the aluminum base 2 move up or down. In this construction, the light source 22 the aluminum base 2 for diffusing or focusing the light rays to the lens 3 or away from the lens 3 emotional.

When moving away the light source 22 from the lens, over the top opening 11 is attached until the light source 22 the bottom of the reflector chamber 14 be achieved, as in the 3 shown - several light beams emitted by the light source on the reflector shield 1 reflected and through the lens 3 broken, after which the rays of light finally through the lens 3 blasted and on the reflector shield 1 and through the lens 3 be bundled.

If the light source - as in the 4 shown - to the lens 3 is moved over the top light-emitting opening 11 is mounted until the light source 22 the upper side of the reflector chamber 14 achieved, are those of the light source 22 emitted light rays only through the lens 3 broken and then from the lens 3 radiated to the outside and scattered.

As in the 1 - 4 shown, the heat dissipation tube extends 21 the aluminum base 2 in the reflector chamber 14 horizontally away from the aluminum base 2 and is dependent on the distance to a bottom of the reflector chamber 14 bent. In this construction, that of the light source 22 generated heat to the aluminum base 2 and then from this to the heat-dissipating tube 21 directed to this from the light source 22 generated heat from the reflector shield 1 To prevent damage caused by the high temperature of the waste heat and thus to maintain the perfect performance, especially the LED lighting fixture.

With reference to the 1 and 9 (which represent the first embodiment) show the 5 and 10 (which represent the second embodiment) or the 6 and 11 (which illustrate the third embodiment) that a slot opening 15 the first embodiment after a Wärmeableitröhrchen 21 and the reflector shield 1 while the second embodiment shows that the two slot openings 15 after the two heat sinks 21 on the reflector shield 1 are aligned. The third embodiment shows that the four slot openings 21 after the reflector shield 1 are aligned. The 9 - 11 The graphs show that the lighting would be attenuated the more, the more slit openings 15 shaped (as shown in the first and third embodiments). However, the illumination corresponding to the third embodiment (90 lux) is lost only 10% as compared with that of the first embodiment (100 lux), so that the attenuation of the illumination is not noticeable when a smaller number of slit openings 15 are shaped. The number of heat sinks 21 that are present in the third embodiment is higher than the number of heat-dissipating tubes 21 that are present in the first and second embodiments, so that the heat in the third embodiment is better dissipated than in the first and second embodiments. The illumination achieved with the third embodiment is less than the illumination achieved with the first two embodiments. If therefore as a light source 22 When an LED light source is used, the manufacturer should consider the third embodiment having the better heat dissipation since prevention of the influence of the waste heat generated at the high temperature is of great importance to the LED light source.

In the 7 For example, the fourth embodiment is illustrated as follows. The number of slit openings 15 is larger than that of the heat sink tubes 21 , In this fourth embodiment, the two slot openings 15 after a heat sink 21 aligned.

In the 8th the fifth embodiment is shown as follows. At least one spiral slot opening 15 is from the lower opening 12 to the upper opening 11 educated. In this construction, the heat-dissipating tube becomes 21 the spiral shape of the slot opening 15 to move the light source to diffuse or focus the light beams in accordance with the movement of the heat dissipation device 21 to the lens 3 or move away from it.

LIST OF REFERENCE NUMBERS

1

reflector shield

11

Upper opening

12

Lower opening

13

Reflector plate back

14

reflector chamber

15

slot opening

2

aluminum base

21

Wärmeableitröhrchen

22

light source

3

lens

Claims (5)

Lighting fixture with low influence by waste heat, comprising: a reflector shield ( 1 ) with an upper opening ( 11 ) at one end and with a lower opening ( 12 ) on the other end; a lens ( 3 ) above the upper opening ( 11 ) is mounted; a reflector shield back ( 13 ) between the upper opening ( 11 ) and the lower opening ( 12 ) of the reflector shield ( 1 ) is shaped; a reflector chamber ( 14 ) between the upper opening ( 11 ), lower opening ( 12 ) and the reflector shield back ( 13 ), and at least one slot opening ( 15 ), the reflector shield back ( 13 ) is formed along; and an aluminum base ( 2 ) at the lower opening ( 12 ) is mounted; at least one heat-dissipating tube ( 21 ) extending from a periphery of the aluminum base ( 2 ), this heat dissipation tube ( 21 ) after the slot opening ( 15 ) is aligned; a light source ( 22 ) based on aluminum ( 2 ) and in the reflector chamber ( 14 ) is movable, and the heat dissipation tube ( 21 ) consists of a highly thermally conductive material; the aluminum base ( 2 ) to the upper opening ( 11 ) or can be moved away from it, wherein the heat dissipation tube ( 21 ) each of the movement of the aluminum base ( 2 ) is moved up or down to the light source ( 22 ) on the aluminum base ( 2 ) for diffusing or focusing the light beams to the lens ( 3 ) or to move away from it. Lighting fixture according to claim 1, characterized in that a size of the aluminum base ( 2 ) is less than the diameter of the lower opening ( 12 ). Lighting fixture according to one of claims 1 to 2, characterized in that a number of heat-dissipating tubes ( 21 ) that of the slot openings ( 15 ), so that a slot opening ( 15 ) a heat dissipation tube ( 21 ), two slot openings ( 15 ) two heat dissipation tubes ( 21 ) and four slot openings ( 15 ) four heat-dissipating tubes each ( 21 ) on the reflector shield ( 1 ) corresponds; where the number of slot openings ( 15 ) larger than that of the heat-dissipating tubes ( 21 ) can be. Lighting fixture according to one of claims 1 to 3, characterized in that at least one spiral slot opening ( 15 ) in the reflector shield back ( 13 ) from the lower opening ( 12 ) to the upper opening ( 11 ) is formed. Lighting fixture according to one of claims 1 to 4, characterized in that the heat dissipation tube ( 21 ) from the aluminum base ( 2 ) in the reflector chamber ( 14 ) horizontally away and depending on the distance to a bottom of the reflector chamber ( 14 ) is bent.

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