EP1482534A2 - Lighting device comprising a gas discharge lamp and a protective sleeve - Google Patents

Abstract

A lighting arrangement has a cylindrical longitudinal gas-discharge lamp (1) with lamp-electrodes (2a,2b) extending into the lamp-body. The screening sleeve or casing (10) is at least partly made of a material with good thermal conductivity or has a layer of such a heat-conducting material. An independent claim is included for a screening sleeve or casing.

Description

The present invention relates to a lighting arrangement consisting of a elongated gas discharge lamp and one for the gas discharge lamp provided shielding consists. In particular, the present invention relates Invention a shielding sleeve for a low-pressure discharge lamp.

The operation of a fluorescent lamp requires that this does not over the entire Length of the lamp body is equally warm. Due to the physical Operations during lamp operation results in a defined location where the Lamp has its lowest temperature during normal operation. This place is commonly referred to as a so-called cool spot.

To operate gas discharge lamps optimally, d. h., during operation To achieve good efficiency, the temperature of the lamps must be within a predetermined range lie. In the so-called T16 lamps, their name obtained due to the fact that their tube has a diameter of 16mm , the optimum temperature range is 40-44 ° C.

The above-mentioned T16 lamps have, in contrast to the likewise known T26 lamps with a wider lamp diameter different lengths Supply lines to the lamp electrodes. This asymmetric Design of a T16 lamp with respect to its electrodes leads to that at these lamps the cool spot comes to rest at the end where the longer Electrode lead is placed, or at which the distance of the electrode to the Front end of the lamp is larger. In contrast, the cool spot is the symmetrically designed T26 lamps always in the middle of the lamp. One episode This is because T16 lamps are more temperature sensitive than T26 lamps.

Are fluorescent lamps, especially the above-mentioned T16 lamps in Air conditioning lights used, so in lights, the supply or exhaust air openings in Have lamp housing, which are connected to an air conditioner, so leads the constant drafts make these lamps cool, d. h., that the Cool Spot has a temperature that is well below 40 ° C. One similar effect arises when lamps with T16 lamps at very low Ambient temperatures are used. Again, the lamp cools down far enough, that the temperature at the cool spot is well below 40 ° C. These Cooling, however, has the consequence that the efficiency of the lamp is no longer optimal.

In order to avoid the above problems, it is known in air conditioning lights, Push plastic sleeves on one side over the one end of the lamp, on the the cool spot is located. In the case of climate luminaires, this can cool down the lamp can be prevented, which is achievable with temperature shield but not for lights that are generally exposed to low temperatures sufficient. Another disadvantage of the known plastic sleeves is also in that they tend to burn off.

The present invention is therefore the object of the known To improve shielding for fluorescent lamps so that with them too low ambient temperatures of the cool spot in an optimal Temperature range are maintained and thus the lamp a sufficiently high Can achieve luminous flux.

The object is achieved by a lighting arrangement according to claims 1 or 2 or by a shielding sleeve for use with a gas discharge lamp solved according to one of the two claims 15 and 16.

According to a first aspect of the present invention, it is proposed that Shielding sleeve designed such that it at least partially made of a material with a good thermal conductivity or a layer of such having good thermally conductive material. According to a second invention Aspect, however, the shielding at least partially consists of a reflective material or has a reflective layer.

Preferably, the shielding sleeve is configured such that it has both properties - So both a good thermal conductivity as well as the ability to reflect electromagnetic radiation - having, for example achieved thereby can be that the shielding at least partially made of metal, especially preferably made of aluminum or a corresponding metal or Aluminum layer has.

Surprisingly, it has been shown that both properties mentioned above contribute to an optimized temperature shield of the lamp over the Environment. The reflective property of the Shielding sleeve that generated at the lamp filament or lamp electrode Heat that is emitted as heat radiation, again reflected back and so the lamp is returned. In addition, it is believed that one Shielding sleeve with high thermal conductivity contributes to that in the adjacent Area of the cool spot of the lamp higher temperature on the area of the Cool To transfer spots. In other words, the shielding itself is heated and desirably conducts this heat to the lamp in the area of the Cool spots over.

To use the second effect of temperature compensation described above Thus, should the shielding sleeve have a high thermal conductivity, these being at least in the range of thermal conductivity of metals should lie. As an indication for this is called the thermal conductivity of lead, which is about 35 W / mK. The material used should therefore be a Have thermal conductivity of greater than or equal to 30 W / mK. The preferred used aluminum even has a conductivity of 220 W / mK.

For the realization of the shielding sleeve there are two possibilities. According to one In the first embodiment, the sleeve can be made of one - preferably transparent - plastic existing basic body consist of at least over a portion of its length or even the entire length with a Layer is coated from a reflective and / or thermally conductive material. In addition, however, there is also the possibility of the shield completely off to form the thermally conductive and / or reflective material. optimal Results were obtained with an aluminum sleeve having a wall thickness of about 1mm and - depending on the ambient temperature - about 35-50mm long.

The shielding sleeve obtained in this way is then at the front end of the Gas discharge lamp is arranged, where the cool spot is located. As already has been mentioned, this is the end of the T16 lamps where the Lamp electrode is located with the longer electrical leads. The Shielding sleeve can be arranged in such a way that, although the electrical Supply lines, but not the lamp electrode itself surrounds. This will despite the - when using metal - opaque shielding sleeve achieved sufficiently high luminous flux. At particularly low However, ambient temperatures can also be used for sleeves which completely surround the electrode due to their length.

The shielding sleeve according to the invention is preferably for use with Low-pressure discharge lamps provided, in particular for use in the T16 lamps described above.

Fig. 1a

eine erfindungsgemäße Beleuchtungsanordnung bestehend aus einer länglichen Gasentladungslampe mit einer erfindungsgemäßen Abschirmhülse in seitlicher Ansicht;

Fig. 1b

die in Fig. 1a dargestellte Beleuchtungsanordnung im Schnitt;

Fig. 2

eine Abschirmhülse gemäß der vorliegenden Erfindung in seitlicher Ansicht; und

Fig. 3

eine Stirnansicht der in Fig. 2 dargestellten Abschirmhülse.

The invention will be explained in more detail with reference to the accompanying drawings. Show it:

Fig. 1a

a lighting arrangement according to the invention consisting of an elongated gas discharge lamp with a shielding sleeve according to the invention in a lateral view;

Fig. 1b

the illumination arrangement shown in Figure 1a in section.

Fig. 2

a shielding sleeve according to the present invention in a side view; and

Fig. 3

an end view of the shielding sleeve shown in Fig. 2.

The lighting arrangement shown in Figs. 1a and 1b consists of a cylindrical elongated gas discharge lamp 1 and one on a front end of the Lamp 1 pushed shielding 10. In the illustrated lamp 1 acts it is a low-pressure discharge lamp, in particular a T16 lamp, whose lamp body 4 has a diameter of 16 mm.

A special feature of the illustrated T16 lamp 1 is that the electrical Feed lines 3a and 3b for the two lamp electrodes 2a and 2b different are long. In the illustrated embodiment, the supply line 3a for the on Lamp electrode 2 a longer arranged left side, which has the consequence that the electrode 2 a further away from the corresponding front end of the lamp 1 is as the electrode 2b. As a result, the cool spot is the lamp 1, so the area at which the lamp 1 in normal operation their lowest temperature has, arranged at the left end of the lamp 1.

In particular, at low ambient temperatures, a cooling of the lamp. 1 in the area of the Cool Spot to a temperature below 40 ° C prevent is on the left front end of the lamp 1 according to the invention Shielding sleeve 10 postponed. In the illustrated embodiment, the Shielding sleeve 10 made entirely of aluminum. As the illustration in Fig. 1a or 1b, the shielding sleeve 10 is so in relation to the Lamp 1 arranged that they are the leads 3a for the lamp electrode 2a surrounds, but not the electrode 2a itself. This ensures that the of the lamp 1 emitted light flux through the opaque aluminum not is impaired.

The surrounding the electrical leads 3a aluminum of the shielding 10th As a result, the heat generated at the electrode 2a is reflected and the Lamp 1 is additionally heated in the forehead area. This ensures that the lamp 1 even at ambient temperatures below 25 ° C still at optimal temperatures can be operated. The left end of the lamp 1, on the cool spot is, is thus through the shielding 10 so far It warmed up that in spite of the low ambient temperatures in the for one optimal lamp operation required temperature range of 40-44 ° C. can be.

The length of the shielding sleeve 10 determines the degree of achievable Temperature increase. There is thus the possibility of choosing the length the shielding sleeve 10 different ambient temperature ranges set at where the shielding 10 achieved the appropriate effects. In other words, it different lengths shielding 10 can be provided, each Sleeve is optimal for a different ambient temperature range.

Preferably, a shielding sleeve 10 made of aluminum has a length 35-50 mm, with the area pushed over the base 10mm long and the area surrounding the glass bulb 4 approx. 25-40mm, especially 30-35 mm long. The wall thickness of the glass bulb 4 enclosing portion of the sleeve 10 is between 0.5mm and 2mm, preferably at about 1mm. It has been shown that with an aluminum sleeve, which has a wall thickness of 1mm and a total length of 40mm, the Temperature at which the lamp can be operated under optimal conditions, can be reduced by about 15 °. Assuming that a T16 lamp without shielding sleeve usually at an ambient temperature between 20 ° should be operated at 30 °, so with this sleeve there is the possibility to operate the lamp optimally at ambient temperatures of 10 ° to 15 °. For an aluminum sleeve with a total length of 45mm, however, the Ambient temperature can even be reduced by about 20 °.

FIGS. 2 and 3 show the shielding sleeve 10 in a lateral view and in FIG Front view. This has - as shown in Fig. 2 - one of the shape of the lamp corresponding inner contour, so that they fit on the front end of the lamp can be put on.

As already mentioned, the shielding sleeve 10 is in the present case made entirely of aluminum, contrary to the original presumption that such an aluminum sleeve has a rather cooling effect, surprisingly has that even with a completely made of aluminum shielding sleeve particularly good results can be achieved. This is attributed to that the aluminum sleeve not only the heat generated at the lamp electrode reflected back, but also warmed up and the heat in desired manner on the lamp in the area of the cool spot.

According to another (not shown) embodiment, however also the possibility of the shielding sleeve from a - preferably transparent - plastic to form existing body, the inside with an aluminum layer or with another layer of a material, the one has high thermal conductivity of at least 30 W / mK and has a reflective effect, is covered. In this variant, of course, there is the possibility To provide shielding sleeves of different lengths, each for different Ambient temperature ranges are suitable.

The present invention thus provides a simple possibility a cooling of a gas discharge lamp, in particular a Low pressure discharge lamp to prevent. The temperature shield by the Shielding sleeve according to the invention is even so good that T16 lamps even at very low ambient temperatures below 25 ° C even at optimum Temperatures can be operated.

Claims (24)

Lighting arrangement comprising
a cylinder-like oblong gas discharge lamp (1), at whose two front ends in each case a projecting into the interior of the lamp body lamp electrode (2a, 2b) and corresponding electrical leads (3a, 3b) are arranged, and
a shielding sleeve (10) surrounding one of the two ends of the lamp (1),
characterized in that the shielding sleeve (10) consists at least partially of a material with a good thermal conductivity or has a layer of such a thermally conductive material. Lighting arrangement comprising
a cylinder-like oblong gas discharge lamp (1), at whose two front ends in each case a projecting into the interior of the lamp body lamp electrode (2a, 2b) and corresponding electrical leads (3a, 3b) are arranged, and
a shielding sleeve (10) surrounding one of the two ends of the lamp (1),
characterized in that the shielding sleeve (10) at least partially consists of a reflective material or has a reflective layer. Lighting arrangement according to claim 1 or 2,
characterized in that the shielding sleeve (10) at least partially consists of metal or has a metal layer. Lighting arrangement according to claim 3,
characterized in that the metal is aluminum. Lighting arrangement according to one of the preceding claims,
characterized in that the shielding sleeve (10) consists entirely of the thermally conductive and / or reflective material. Lighting arrangement according to one of claims 1 to 4,
characterized in that the shielding sleeve (10) consists of a basic body made of plastic, which is covered at least over a part of its length with a layer of thermally conductive and / or reflective material. Lighting arrangement according to claim 6,
characterized in that the layer of thermally conductive and / or reflective material covers the base body over the entire length. Lighting arrangement according to claim 6 or 7,
characterized in that the base body consists of a transparent plastic. Lighting arrangement according to one of the preceding claims,
characterized in that the shielding sleeve (10) is arranged with respect to the gas discharge lamp (1) so as to surround only the electrical leads (3a, 3b) of the corresponding lamp electrode (2a, 2b) but not the lamp electrode (2a, 2b ) even. Lighting arrangement according to one of the preceding claims,
characterized in that the electrical leads (3a, 3b) for the lamp electrodes (2a, 2b) are of different lengths, wherein the shielding sleeve (10) at the front end of the lamp electrode (2a, 2b) with the longer electrical leads (3a, 3b) is arranged. Lighting arrangement according to one of the preceding claims,
characterized in that the gas discharge lamp is a low-pressure discharge lamp (1). Lighting arrangement according to claim 11,
characterized in that the gas discharge lamp is a T16 lamp. Lighting arrangement according to one of the preceding claims,
characterized in that the shielding sleeve (10) has a length of about 35-50 mm, wherein the region surrounding the glass bulb (4) of the lamp (1) is about 25-40 mm, in particular 30-35 mm long , Lighting arrangement according to claim 13,
characterized in that the glass bulb (4) of the lamp (1) enclosing region of the shielding sleeve (10) has a wall thickness between 0.5 mm and 2 mm, in particular of about 1 mm. Shielding sleeve (10) for use in a cylinder-like oblong gas discharge lamp (1), at the two ends of which a lamp electrode (2a, 2b) projecting into the interior of the lamp body and corresponding electrical leads (3a, 3b) are arranged,
wherein the shielding sleeve (10) is to be arranged with respect to the gas discharge lamp (1) in such a way that it surrounds one of the two front ends,
characterized in that the shielding sleeve (10) consists at least partially of a material with a good thermal conductivity or has a layer of such a thermally conductive material. Shielding sleeve (10) for use in a cylinder-like oblong gas discharge lamp (1), at the two ends of which a lamp electrode (2a, 2b) projecting into the interior of the lamp body and corresponding electrical leads (3a, 3b) are arranged,
wherein the shielding sleeve (10) is to be arranged with respect to the gas discharge lamp (1) in such a way that it surrounds one of the two front ends,
characterized in that the shielding sleeve (10) at least partially consists of a reflective material or has a reflective layer. Shielding sleeve according to claim 15 or 16,
characterized in that it consists at least partially of metal or has a metal layer. Shielding sleeve according to claim 17,
characterized in that the metal is aluminum. Shielding sleeve according to one of claims 15 to 18,
characterized in that it consists entirely of the thermally conductive and / or reflective material. Shielding sleeve according to one of claims 15 to 18,
characterized in that it consists of a basic body made of plastic, which is coated over at least part of its length with a layer of thermally conductive and / or reflective material. Shielding sleeve according to claim 20,
characterized in that the layer of thermally conductive and / or reflective material covers the base body over the entire length. Shielding sleeve according to claim 20 or 21,
characterized in that the base body consists of a transparent plastic. Shielding sleeve according to one of claims 15 to 22,
characterized in that the shielding sleeve (10) has a length of about 35-50 mm, wherein the area surrounding the glass bulb (4) of the lamp (1), about 25-40 mm, in particular 30-35 mm long is. Shielding sleeve according to claim 23,
characterized in that the glass bulb (4) of the lamp (1) enclosing region of the shielding sleeve (10) has a wall thickness between 0.5 mm and 2 mm, in particular of about 1 mm.

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