DE19737920A1 - Long life low pressure gas discharge lamp - Google Patents

Abstract

The discharge vessel of a low pressure gas discharge lamp is in the form of an outer bulb surrounding an inner bulb which contains mercury vapor and/or metal vapor generating compounds and/or noble gases and which is transparent to electromagnetic radiation resulting from fluorescence excitation of the gas filling, phosphor being provided on the outside of the inner bulb and/or the inside of the outer bulb. A long life low pressure gas discharge lamp, especially a mercury vapor lamp, having a column power of more than 200 W/m<2> and a gas discharge UV emission of greater than 3.5 eV energy, has a discharge vessel as above.

Description

The invention relates to a low-pressure gas discharge lamp, in particular a mercury Over-steam low-pressure discharge lamp, with increased service life.

Gas discharge lamps produce with the help of the discharge of the excited gas from suitable phosphors visible light for lighting purposes. Particularly common are compact low-pressure mercury vapor discharge lamps, consisting of one Vacuum-tight glass bulb filled with mercury and inert gas is provided on the inside with a layer of fluorescent that contains the short-wave mercury resonance radiation with energies of about 6.71 eV and 4.88 eV into visible light delt.

The disadvantage of these known mercury vapor low-pressure discharge lamps be is that by the action of short-wave UV radiation on the phosphor layer and by the recombination of mercury ions with electrons on the phosphor surface or by the incidence of excited mercury atoms and electrons on the Phosphor layer the emissivity of the phosphor with the duration of the Einwir kung decreases significantly, which results in a sharp decrease in light output prey or the luminous flux with the lamp burning time.

Furthermore, the disposal of the gas discharge lamps that have become unusable is technolo technically complicated because the reprocessing and recovery of the expensive phosphor mixing is difficult and costly or even impossible because of the phosphors are heavily contaminated with mercury and other discharge components.

By Tews, W. et al in Z. phys. Chemie, Leipzig 267 (1986) pp. 97-105 and pp. 145-152 and in 268 (1987) pp. 81-90, it is described that the exposure to UV radiation proportion of the fluorescent damage attributable to nature and the pressure of the Phosphor surrounding gas atmosphere depends. Damage to the phosphor caused by UV radiation occurs particularly in a vacuum or in inert gases. In contrast, in Va in a vacuum or in inert gases damaged by short-wave UV radiation subsequent irradiation with the same radiation source in an oxygen-containing atmosphere completely or almost completely regenerated.

Sufficient technical solutions for the effective extension of the service life the low-pressure gas discharge lamps are not yet known.

The invention is therefore based on the object of a long-lasting low-pressure gas outlet to provide the light source. During the burning of the gas discharge  lamp the decrease in luminous flux due to the phosphor over a long period Period essentially only that of the so-called UV-induced short-term drop ent should speak, so that the total luminous flux or the luminous efficacy over the entire Lamp life only slightly deteriorated.

According to the invention, this object is achieved by a low-pressure gas discharge lamp, consisting of a vacuum-tight inner bulb, which is filled with mercury vapor and / or metal vapor generating compounds and / or noble gas and filled for electroma genetic radiation that arises when the respective gases are excited to fluoresce, is permeable, and from means for maintaining the gas discharge and from one the inner bulb of the gas discharge lamp surrounding the outer bulb, which is also above all is manufactured in a vacuum-tight manner and is permeable to electromagnetic radiation and whose is coated with a fluorescent layer on the inside. According to the invention, however, the Fluorescent layer on the outside of the inner bulb or on the inside of the outside bulb and arranged on the outside of the inner bulb of the gas discharge lamp the.

The arrangement according to the invention of the two nested pistons in the gas discharge lamp prevents the spatial separation of the phosphor from the gas ent charge the phosphor is no longer directly exposed to the gas discharge. By separation of the phosphor from the gas discharge is advantageously the direct action of Mercury and other discharge components such. B. sputtered electrodes material on the phosphor layer avoided.

The UV radiation generated during gas discharge penetrates through the electromagnetic field radiation permeable inner bulb of the discharge lamp and is from the light layer of material that is on the inside of the outer bulb and / or on the outside of the Inner bulb located, converted into visible light.

The with mercury vapor and / or metal vapor generating compounds and / or Noble gases filled inner bulb of the gas discharge lamp is at least for electromagnetic cal radiation of an energy permeable, as in the excitation of these gases in the gas discharge occurs. This transmitted gas discharge radiation changes in the Fluorescent layer in visible light.

The pillar power related to the inside of the inner bulb, ie the UV radiation power emitted by the positive pillar, based on the inner surface of the inner bulb, is preferably greater than 200 Wm ^-2 and essentially has energies greater than 3.5 eV . The radiation proportions in the respective UV radiation energy are different and depend on the geometric shape and the diameter of the tube of the inner bulb of the gas discharge lamp. When using a mercury vapor low-pressure discharge lamp, the proportion of radiation energy of 6.71 eV increases as the diameter of the inner bulb is reduced to 1 mm. With inner bulb diameters greater than 15 mm, the proportion of radiation energy of 4.88 eV dominates more and more, so that in such preferred embodiments the decrease in the emissivity of the phosphors is further reduced. The inner bulb of the gas discharge lamp is preferably made of quartz glass or another material which is permeable to UV radiation.

Another preferred embodiment of the invention is an electro detachable gas discharge lamp with inductive or capacitive coupling into the inner bulb tem low-pressure plasma of any nature, the inner bulb made of quartz glass or a other material that is permeable to UV radiation.

The outer bulb that is permeable to visible radiation with energy of less than 4.5 eV According to the invention, the gas discharge lamp can have any shape. Prefers is the shape of a ball, pear or an ellipsoid. This enables, too to realize the usual form of incandescent lamp for gas discharge lamps Traffic has got used to for decades.

In a preferred embodiment of the invention, the gas discharge lamp has an mi niaturized inner piston, which is comparatively small and made of one UV radiation permeable material. The discharge atmosphere are besides noble gases Mercury and / or other metals are added, with the gas discharge in the inner bulb lamp a medium-pressure mercury noble gas discharge can be generated.

In a preferred development of the invention, that is between the inner piston and the outside Bulb of the gas discharge lamp formed space with a gas or a gas mixture filled as filling gas. This further training enables a further reduction in waste the emissivity with increasing burning time of the gas discharge lamp and thus associated a further increase in lifespan. By creating a suitable one The atmosphere between the inner bulb and the outer bulb of the gas discharge lamp is also that Damage to the phosphor fully except for the short-term drop in the selected atmosphere constantly avertable. For this purpose, suitable gases at a suitable pressure are from the inside bulb and outer bulb formed space of the gas discharge lamp added, the one aging induced by UV radiation except for the short-term drop already mentioned prevent. Oxygen is a particularly suitable gas for this.  

To create a suitable atmosphere between the inner and outer bulb of the gas Charge lamps are preferably one or more of the phosphor of the phosphor layer added chemical compounds that under the influence of gas discharge one or more Release more filling gases up to a desired vapor pressure. Alternatively, the fill gas in the manufacture of the gas discharge lamp directly into the space between the interior and Outer bulb filled with the desired pressure. As filling gases are special Oxygen and / or oxygen compounds and / or nitrogen and / or noble gases is suitable. The total pressure of the fill gases is greater than 0.001 pascals, with the preferred one Pressure of the gas atmosphere between the inner and outer bulbs of the gas discharge lamp from the respective phosphor or the respective phosphor mixture and the one used Filling gas depends.

The design of the gas discharge lamp according to the invention also permits use from other than the usual rare earth activated fluorescent systems that are cheaper and eco are nomically cheaper to produce than the latter phosphors.

If a halogen-containing phosphor is used for the phosphor layer, then the Gas atmosphere between the inner and outer bulbs of the gas discharge lamp prefers Ha add logical or halogen compounds.

In the case of the use of sulfur-containing phosphors in the phosphor layer the gas atmosphere between the inner and outer bulbs of the gas discharge lamp advantageous sulfur-containing compounds or sulfur to maintain a certain sulfur add partial pressure.

In the case of phosphor systems with easily oxidizable components, the gas atmosphere is between inner and outer bulbs of the gas discharge lamp preferably hydrogen or a to supply other reducing chemical compound.

The gas discharge lamp according to the invention preferably has a phosphor layer that the selection criterion met that the decrease in the relative luminance of a defined Sample of the phosphor or the phosphor mixture, based on the respective unbe beamed samples in a suitable gas atmosphere even with long-term exposure up to 20,000 hours of low-pressure mercury radiation with a total UV exposure strength of 50-1500 W m and with a lamp-specific power ratio of Resonance lines at energies of 6.71 eV and 4.88 eV between 0.1 and 2.0 and at tem temperatures between 290 K and 400 K a certain value, which is generally below 5% lies, does not exceed.  

Such phosphors create when used in the gas discharge lamp according to the invention a quasi-aging-free light source. The decrease due to the phosphor the luminance over a long period up to 20,000 operating hours and more speaks at most of the UV-induced short-term drop. A stationary door is created stood with an almost constant value of luminance or luminous flux and ei ner almost constant spectral distribution of the emission light and thus an approx constant color rendering.

The phosphor used for the gas discharge lamp according to the invention therefore continues to meet, alternatively or cumulatively, the selection criterion that when using phosphors previously damaged in a vacuum or in inert gases by UV radiation, when exposed to low-pressure mercury radiation with a total UV Irradiance of 50-1500 Wm ^-2 and with a lamp-specific power ratio of the resonance lines at energies of 6.71 eV and 4.88 eV between 0.1 and 2.0 as well as at temperatures between 290 K and 400 K in a suitable gas atmosphere the short-term drop in UV radiation-induced relative luminance of the phosphor, based on the unirradiated phosphor, up to a difference of at most 5%.

In a suitable gas atmosphere, i.e. that is, with a suitable filling gas at a suitable pressure, the in the regeneration process achievable luminance of the phosphor resulting from the UV radiation-induced short-term drop under the same conditions and resulting value even exceed the value of the non-irradiated phosphor.

The luminescent materials based on are advantageously found in the luminescent layer of the gas discharge lamp according to the invention

• - alkaline earth halophosphate
• - cerium magnesium aluminate,
• - alkaline earth aluminate,
• - Ln phosphate,
• - Ln phosphate silicate,
• - Ln oxide,
• - gadolinium magnesium pentaborate,
• - magnesium fluorogermanate,
• - barium disilicate,
• - alkaline earth borate,
• - alkaline earth orthophosphate,  
• - alkaline earth pyrophosphate,
• - alkaline earth orthosilicate,
• - zinc orthosilicate,

or a combination of these phosphors application, the phosphors with ions rare earths, especially with ions of europium, terbium, gadolinium, cerium, Dysprosium, samarium and praseodymium, and / or ions of manganese, lead, antimony, Tin and bismuth are activated and the alkaline earth metal cations partly due to ions of the elements Te of the 2nd sub-group substituted or the rare earth elements such as lanthanum partially or can be completely replaced by ions of the 3rd subgroup.

The invention is described below with reference to the figures of the drawing Embodiment explained in more detail. Show it

Fig. 1 shows schematically a gas discharge lamp according to the invention and

Fig. 2 for different phosphors, the dependence of the relative luminance on the logarithm of the pressure of the gas surrounding the phosphor at egg ner irradiation time of 50 hours.

In Fig. 1, the mercury vapor low-pressure discharge lamp according to the invention is shown schematically with an inner and outer bulb. The gas discharge lamp has the socket 1 and the base 2 . In the socket 1 or in the base 2 , an electrical ballast is integrated in a manner known per se, which regulates the ignition and the operation of the gas discharge lamp. In a further embodiment of the gas discharge lamp with base pins, not shown in FIG. 1, the gas discharge lamp can also be operated and regulated via an external ballast.

According to Fig. 1 of the gas discharge lamp is on the base 2 of the vacuum-tight inner plunger 3 is placed, of holding a mixed gas of mercury and rare gas, for example argon ent. The inner bulb 3 is designed as a multiply folded quartz or UV rays - permeable glass tube, as is known for example from DE 42 14 542 A1.

In the inner bulb 3 of the gas discharge lamp project two electrodes connected to the ballast, not shown in FIG. 1, between which the gas discharge is ignited. The gas discharge mainly produces UV radiation energies of 6.71 eV and 4.88 eV, the ratio of the two to one another depending on the selected dimensions of the inner bulb 3 of the gas discharge lamp and on the strength of the discharge current.

Alternatively, the gas discharge lamp is an electrodeless lamp in which 3 low-pressure plasma is inductively or capacitively coupled into the inner bulb.

The inner bulb 3 is surrounded by the vacuum-made outer bulb 4 of the gas discharge lamp, which is also placed on the base 2 . The phosphor layer 5 is arranged on the inside of the outer bulb. The hermetically sealed intermediate space 6 which arises between the inner bulb 3 and the outer bulb 4 of the gas discharge lamp contains a gas or a gas mixture which in particular contains oxygen, the total pressure of the gas filling the intermediate space 6 being greater than 0.001 Pascal.

The UV radiation of the gas discharge in the inner bulb 3 penetrates its wall and strikes the phosphor layer 5 on the inside of the outer bulb 4 , absorbing it and converting it into visible light which penetrates through the wall of the outer bulb 4 to the outside. Alternatively or cumulatively, the phosphor layer 5 can be arranged on the outside of the inner bulb 3 , visible light likewise occurring in the phosphor layer on the outside of the inner bulb 3 as an alternative or in addition to the light generated in the phosphor layer 5 on the inside of the outer bulb 4 by luminescence .

The phosphor layer 5 and the gas filling of the intermediate space 6 of the gas discharge lamp are matched to one another by suitable choice of the phosphors as well as the gas filling and the pressure used such that the damage to the phosphor is eliminated except for the short-term drop induced by UV radiation. Experiments on three-band fluorescent materials made of CAT, BAM and YOX as well as halophosphate fluorescent materials when irradiated with mercury low-pressure radiation under various conditions have proven the pressure dependence of UV-radiation-induced aging and furthermore that above a certain pressure only the short-term drop induced by UV radiation occurs.

Corresponding measurement results at a UV irradiance of 100 Wm ^-2 are shown graphically in FIG. 2 for three calcium halophosphate phosphors and for the three-band phosphors BAM, CAT and YOX. The relative luminance is plotted as a function of the pressure during the irradiation, P ₀ being 1 Pascal.

It can be clearly seen that above a certain, depending on the respective phosphor only the so-called short-term loss occurs under pressure. The location of the turning point the S-shaped curve and thus both the speed and the extent of aging and regeneration, as well as the position of the steady state, depends on selected gas filling only depends on the fluorescent system used and its quality.

As a gas atmosphere in the space 6 between the inner bulb 3 and the outer bulb ben 4 of the gas discharge lamp according to the invention according to FIG. 1, an oxygen atmosphere with a pressure of at least 100 Pascal is used in the exemplary embodiment according to FIG. 2. The steady state which arises in the case of the phosphors mentioned in FIG. 2 determines an approximately constant value of the luminance over a long period of time up to 20,000 operating hours and more. It depends very little on the chosen discharge conditions in the inner bulb 3 of the gas discharge lamp.

In alternative embodiments of the gas discharge lamp according to the invention, at halogen-containing phosphor layers to the fill gas halogens or halogen compounds and added sulfur or sulfur compounds in the case of phosphors containing sulfur.

In alternative exemplary embodiments, the following phosphors or a combination of the following phosphors are found for the gas discharge lamp according to the invention
CHP - calcium halophosphate: Sb and / or Mn,
SCP - strontium chlorophosphate: Eu and (Ba, Sr, Ca) - chlorophosphate: Eu,
CAT - cerium magnesium aluminate: Tb,
BAM - barium magnesium aluminate: Eu,
LAP - lanthanum phosphate: Ce, Tb,
LAPS - lanthanum phosphate silicate: Ce, Tb,
Yox yttrium oxide: Eu,
CBT - Gadolinium - Magnesium Pentaborate: Ce, Tb,
CBM - Cerium - Gadolinium - Magnesium Pentaborate: Mn,
MgFG - magnesium fluorogermanate: Mn (IIII),
OPS - Strontium Magnesium Orthophosphate: Sn,
ZSM - Zinc Orthosilicate: Mn,
BSOSE - Barium Strontium Orthosilicate: Eu,
SAE - strontium aluminate: Eu
Application.

These phosphors or combinations of these phosphors are used in an atmosphere in the space 6 between the inner bulb 3 and the outer bulb 4 of the inventive gas discharge lamp made of air or oxygen at a pressure greater than 6-8 Pascal. In the case of all phosphors, the decrease in the relative luminance or radiance when excited with 4.88 eV radiation over a period of 50 hours with a total UV irradiance of 150-1500 Wm ^{-2 is} less than 5% in a corresponding gas atmosphere, this being The value corresponds approximately to the short-term decline and is already reached after about 2-3 hours. Likewise, the value of the short-term drop is reached or even exceeded in a regeneration process when phosphors previously damaged by UV radiation in a vacuum are used.

Further exemplary embodiments relate to the use of some phosphors which emit UV radiation and which, under the radiation conditions mentioned, behave analogously to the phosphors already mentioned. It is the phosphors
Barium disilicate: Pb,
Strontium magnesium aluminate: Ce,
Barium fluorophosphate: Pb, Gd,
Strontium hexaborate: Pb,
Strontium tetraborate: Eu and strontium fluoroborate: Eu,
Strontium Magnesium Pyrophosphate: Eu.

With all of these UV phosphors, the decrease in the relative radiance when excited with a UV radiation energy of 4.88 eV over a period of 50 hours with a total UV irradiance of 150-1500 Wm ^-2 likewise occurs in a corresponding gas atmosphere less than 5% and is reached after 2-4 hours.

The gas discharge lamp according to the invention can also be designed for high luminance or beam densities. The inner bulb 3 of the gas discharge lamp is made from a quartz tube or a glass tube that is transparent to UV radiation.

Claims (17)

1. Low pressure gas discharge lamp with increased life, in particular mercury vapor low pressure discharge lamp, with a gas discharge vessel, the related column power is greater than 200 Wm ^-2 and the resulting UV radiation in the gas discharge essentially energies greater than 3.5 eV, and means for generating and maintaining a gas discharge, characterized in that the discharge vessel forms an inner bulb which is permeable to electromagnetic radiation and is surrounded by an outer bulb, and the outside of the inner bulb and / or the inside of the outer bulb are provided with a fluorescent layer and the inner bulb contains mercury vapor and / or metal vapor-producing compounds and / or noble gases and is permeable to electromagnetic radiation which arises when the respective gases are excited to fluoresce. 2. Gas discharge lamp according to claim 1, characterized in that the inner bulb from a glass that is permeable to the mercury radiation energy at 4.88 eV preferably quartz glass and other UV-permeable material, and that Gas discharge mainly a radiation according to the discharge conditions generated energy of 4.88 eV. 3. Low-pressure gas discharge lamp with increased service life according to claim 1 and 2, characterized in that in the inner bulb low-pressure plasma of any nature is inductively or capacitively coupled. 4. Low pressure gas discharge lamp with increased lifespan after at least one of the preceding claims, characterized in that the outer bulb ball is shaped, pear-shaped or ellipsoidal. 5. Gas discharge lamp according to at least one of the preceding claims, characterized characterized in that the outer bulb for electromagnetic radiation with energies is less than 4.5 eV permeable. 6. Low pressure gas discharge lamp with increased lifespan after at least one of the preceding claims, characterized in that the gas discharge lamp  has a miniaturized inner bulb and the discharge atmosphere mercury over and / or other metals are added. 7. Low pressure gas discharge lamp with increased service life after at least one of the preceding claims, characterized in that the inner col ben and outer bulb formed space with a filling gas or a gas mixture is filled. 8. Low-pressure gas discharge lamp with increased life according to claim 7, there characterized in that the phosphor or the phosphor layer on the Kol benwänd one or more compounds are added, which under the influence of Ga discharge releases one or more filling gases up to a desired vapor pressure Zen. 9. Low-pressure gas discharge lamp with increased service life according to claim 7 or 8, characterized in that oxygen and / or oxygen compounds as the filling gas and / or nitrogen and / or noble gases are used. 10. Low pressure gas discharge lamp with increased lifespan after at least one of claims 7 to 9, characterized in that for the phosphor layer halogen-containing phosphor is used and the gas atmosphere between the inner col ben and outer bulb halogens or halogen compounds are added. 11. Low pressure gas discharge lamp with increased service life after at least one of claims 7 to 10, characterized in that for the phosphor layer sulfur-containing compounds are used and the gas atmosphere between In piston and outer piston by adding a sulfur-containing compound or a certain sulfur partial pressure in the gas space through the direct addition of sulfur having. 12. Low pressure gas discharge lamp with increased service life after at least one of claims 7 to 11, characterized in that with fluorescent systems with easily oxidizable components of the gas atmosphere between the inner bulb and Au  ßenkolben hydrogen or another reducing compound added is 13. Low pressure gas discharge lamp with increased service life after at least one of claims 7 to 12, characterized in that the total pressure of the filling gases is greater than 0.001 Pascal. 14. Low-pressure gas discharge lamp with increased service life according to at least one of the preceding claims 1 to 13, characterized in that as luminous substances

• - alkaline earth halophosphate,
• - cerium magnesium aluminate,
• - alkaline earth aluminate,
• - Ln phosphate,
• - Ln phosphate silicate,
• - Ln oxide,
• - gadolinium magnesium pentaborate,
• - magnesium fluorogermanate,
• - barium disilicate,
• - alkaline earth borate,
• - alkaline earth orthophosphate,
• - alkaline earth pyrophosphate,
• - alkaline earth orthosilicate,
• - zinc orthosilicate,
  or a combination of these phosphors can be used, the phosphors being activated with rare earth ions, in particular with ions of europium, terbium, gadolinium, cerium, dysprosium, samarium and praseodymium, and or ions of manganese, lead, antimony, tin and bismuth are and the alkaline earth metal cations are partially substitutable by ions of the elements of subgroup 2 or the rare earth elements lanthanum are partially or completely replaceable by ions of subgroup 3.

15. Low-pressure gas discharge lamp with increased service life according to at least one of the preceding claims 1 to 15, characterized in that in particular the phosphors
CHP - calcium halophosphate: Sb and / or Mn,
SCP - strontium chlorophosphate: Eu and (Ba, Sr, Ca) chlorophosphate: Eu,
CAT - cerium magnesium aluminate: Tb,
BAM - barium magnesium aluminate: Eu,
LAP - lanthanum phosphate: Ce, Tb and
LAPS - lanthanum phosphate silicate: Ce, Tb,
Yox - yttrium oxide: Eu,
CBT - Gadolinium Magnesium Pentaborate: Ce, Tb,
CBM - Cerium Gadolinium Magnesium Pentaborate: Mn
MgFG - magnesium fluorogermanate: Mn (IIII),
OPS - Strontium Magnesium Orthophosphate: Sn
ZSM - Zinc Orthosilicate: Mn,
BSOSE - Barium Strontium Orthosilicate: Eu,
SAE - strontium aluminate: Eu
such as
Barium disilicate: Pb,
Strontium magnesium aluminate: Ce,
Barium fluorophosphate: Pb, Gd,
Strontium hexaborate: Pb,
Strontium tetraborate: Eu and strontium fluoroborate: Eu,
Strontium Magnesium Pyrophosphate: Eu
or a combination of these phosphors can be used. 16. Low-pressure gas discharge lamp with increased service life according to at least one of the preceding claims 1 to 15, characterized in that in particular the phosphors
CHP - calcium halophosphate: Sb and / or Mn,
SCP - strontium chlorophosphate: Eu and (Ba, Sr, Ca) chlorophosphate: Eu,
CAT - cerium magnesium aluminate: Tb,
BAM - barium magnesium aluminate: Eu,
LAP - lanthanum phosphate: Ce, Tb and
LAPS - lanthanum phosphate silicate: Ce, Tb,
Yox - yttrium oxide: Eu,
CBT - Gadolinium Magnesium Pentaborate: Ce, Tb,
CBM - Cerium Gadolinium Magnesium Pentaborate: Mn
MgFG - magnesium fluorogermanate: Mn (IIII),
OPS - Strontium Magnesium Orthophosphate: Sn,
ZSM - Zinc Orthosilicate: Mn,
BSOSE - Barium Strontium Orthosilicate: Eu,
SAE - strontium aluminate: Eu
such as
Barium disilicate: Pb,
Strontium magnesium aluminate: Ce,
Barium fluorophosphate: Pb, Gd,
Strontium hexaborate: Pb,
Strontium tetraborate: Eu and strontium fluoroborate: Eu,
Strontium Magnesium Pyrophosphate: Eu
or a combination of these phosphors can be used. 17. Gas discharge lamp according to at least one of the preceding claims 1 to 15, characterized in that a rod-shaped embodiment for high luminous or Radiance can be used in which the inner column containing the gas discharge ben from a quartz tube of different dimensions or one UV-permeable glass tube, which are coated on the outside with fluorescent, be stands and the outer bulb coated with fluorescent on the inside, the is designed as a tube, is arranged above, the between the two tubes trained space is filled with filling gas.