EP1357580A2 - Low pressure discharge lamp with end of life shutdown means - Google Patents

Abstract

The device has a tubular discharge vessel, 2 electrode systems (3) and a device for shutting off the lamp at the end of its life with of a paste (9) containing a metal hydride applied to a glass bead (8) with a specific electrical resistance greater than 108 Ohm cm. at 350 degrees C. The paste is arranged in the bead's thermal radiation shadow relative to the coil's (7) thermal radiation and has no connection to current feed wires on the bead.

Description

Technical field

The invention relates to a low-pressure discharge lamp with a tubular Discharge vessel made of glass, the free ends of which are sealed gas-tight are, with two electrode systems, each with a coil, two power supplies and a pearl made of glass, the power supplies with their Ends in the gas-tight sealed ends of the discharge vessel and for holding in an area between the filament and the discharge vessel melt are melted into the pearl and with a device to switch off the lamp at the end of its life consisting of a paste that contains a metal hydride and is attached to the pearl.

State of the art

Such a low-pressure discharge lamp is known from European patent EP 0 727 809 known. At the end of the life of the low pressure discharge lamp, if the coil breaks or the emitter material is used up is, the lamp goes into a cold cathode operation, which is an increase the cathode drop voltage and thus a strong heating of the metal parts in the lamp. The sharp rise in the temperature of the Metal parts lead to decay of the metal hydride in the paste, which in the radiation area the helix and with contact to the power supply lines on the Glass bead is attached. By the decay of the metal hydride, in particular Titanium hydride is released and the discharge due to the increasing lamp lamp voltage extinguished.

An arrangement of the paste containing metal hydride in the radiation area the coil and in thermal contact with the power leads leads to one safe release of the hydrogen and thus extinguishing the lamp at the end of life. However, it has been shown that such Construction lead to early failures of the low-pressure discharge lamp can, if this is operated on a ballast that is in the preheating phase allows the filament heating current to rise until the lamp ignites Has. In this case, the increase in the spiral radiation and the Heating the power supply leads to premature decomposition of the metal hydride have as a consequence. The released hydrogen then becomes the The lamp has been extinguished due to emitter consumption before the end of its service life.

Presentation of the invention

The object of the invention is therefore a lamp with a device for switching off according to the low pressure discharge lamp at the end of its service life to provide the preamble of claim 1, due to early failures high spiral heating currents of the ballast can be prevented.

This task is performed on a low-pressure discharge lamp with the features of the preamble of claim 1 by the features of the characterizing Part of claim 1 solved. Particularly advantageous configurations can be found in the dependent claims.

By using a material for the pearl that has at least a specific electrical resistance of greater than 10 ⁸ Ωcm at 350 ° C., it can be ensured that the material of the pearl does not become conductive up to the decomposition temperature of the metal hydride. Heating of the metal hydride by direct heat conduction is largely prevented.

Furthermore, the paste with the metal hydride is according to the invention with respect to heat radiation emanating from the filament of the lamp during operation Radiant shadows applied to the pearl. This can cause heating the paste and thus the metal hydride through direct heat radiation prevented by the helix. In addition, the paste is so on applied to the pearl, making no electrical contact with the power supply wires has. This will result in heat conduction from the power supply largely prevented in the paste.

The pearl therefore advantageously consists of a potassium barium silicate glass which has a specific electrical resistance of greater than or equal to 10 ¹⁰ Ωcm at 350 ° C. An electrical conduction of the pearl is optimally prevented up to the release temperature of the hydrogen at 400 ° C.

Furthermore, the glass bead advantageously has no spherical shape, but one circular cylindrical or cylindrical shape, the axis of which is transverse to the axis of the Discharge vessel is aligned in this area, the power supplies melted near the two ends of the circular cylindrical bead are and the paste with the metal hydride on the of the helix part of the pearl turned away in the radiation shadow of the coil is. A mushroom-like shape is also advantageous, the cap of the mushroom being the Wendel is facing and the paste with the metal hydride is below the Cap is located in the radiation shadow of the coil. This will be optimal heating of the paste and thus of the metal hydride by the radiant heat prevented.

The investigations with different shapes and sizes for the pearl showed that in the case of a circular cylindrical or roller-shaped pearl, the circle should advantageously have a diameter d in mm, which obeys the following empirical formula: d> 0.2026 xm + 1.7617 with m ≥ 2 mg where m is the amount of the metal hydride paste in mg. Otherwise, the required amount of paste cannot be applied safely in the shadow of the coil and without contact with the power supply.

In addition, it has a gas-tight seal for the discharge vessel facing next point of the pearl at least a distance of 2 mm from this closure. If this is not observed, it can be closed of the discharge vessel during lamp manufacture and the same occurring great heat to a glazing of the pearl and thus a Release of the hydrogen come from the metal hydride compound.

The metal hydride in the paste advantageously contains a metal from the group Titanium, zirconium and / or hafnium or a metal alloy from the group of Alloys titanium-zircon, titanium-hafnium and / or zircon-hafnium as metal for the metal hydride.

A rheological material is particularly suitable as the paste material for the metal hydride Additive with a proportion of 50% by weight or less.

Best results can be achieved with a paste that contains titanium hydride TiH ₂ as the metal hydride. Investigations showed that the release of the hydrogen increases with the increase in the surface to volume ratio of the titanium hydride grains, so that the smaller the grain size of the titanium hydride, the more hydrogen is released. Shutdown due to the release of hydrogen during the preheating phase could be optimally prevented with a paste with titanium hydride TiH ₂ , which has an average grain size of greater than 50 µm.

Brief description of the drawings

Figur 1

ein Ende eines erfindungsgemäßen Ausführungsbeispiels einer Niederdruckentladungslampe mit einer kreiszylinder- oder walzenförmigen Perle

Figur 2

ein Ende eines zweiten erfindungsgemäßen Ausführungsbeispiels einer Niederdruckentladungslampe mit einer pilzförmigen Perle

The invention is to be explained in more detail below on the basis of several exemplary embodiments. Show it:

Figure 1

one end of an embodiment of a low-pressure discharge lamp according to the invention with a circular-cylindrical or roller-shaped pearl

Figure 2

one end of a second embodiment of the invention of a low-pressure discharge lamp with a mushroom-shaped pearl

Preferred embodiments of the invention

Figure 1 shows one end of a first embodiment of a compact low-pressure discharge lamp with a multi-curved discharge vessel. The ends of the discharge vessel are closed by crushing, in which is shown here and sealed gas-tight by a pinch 2 End 1 of the discharge vessel, the two power supplies 5, 6 one Electrode system 3 are melted down. The electrode system exists continue from a coil 7 and a glass bead 8, which is approximately in located in the middle between the helix 7 and the pinch 2 and into the the two power supply lines 5.6 are melted down. The glass bead 8 is made made of a potassium barium silicate glass and has one essentially circular cylindrical or cylindrical shape with rounded ends, where the axis of the cylinder or the roller transverse to the axis of the discharge vessel runs in this area. The bead 8 has a length of 7 mm and a circle diameter of 4 mm. The two power supplies 5, 6 are melted near the two ends of the pearl 8. On the of the Helix 7 facing away from the lateral surface is a paste 9 from a Titanium hydride and a rheological additive applied, the body with the paste in the radiation shadow with respect to the coil 7.

Figure 2 shows a second embodiment of a discharge vessel end 10 of a compact low-pressure discharge lamp with a similar structure of the electrode system. The end of the discharge vessel 10 with the Crush 11 is rotated by 90 ° in its axis. The electrode system 12 with a coil 13 and power supplies 14 (it is in this View only one power supply visible) differs from the system in Figure 1 in that here the pearl 15 made of a potassium barium silicate glass has a mushroom shape with a cap 16 and a stem 17, the cap 16 facing the coil 13. Doing so which is applied below the cap 16 on both sides of the stem 17 Paste 18 with the titanium hydride in the radiation shadow of the coil 13.

Claims (11)

Low pressure discharge lamp with a tubular discharge vessel made of glass, the free ends of which are sealed gas-tight two electrode systems (3; 12), each with a coil (7; 13), two current leads (5, 6; 14) and a pearl (8; 15) made of glass, the current leads (5, 6; 14) with their ends are melted into the gas-tight ends of the discharge vessel and for holding in an area between the helix (7; 13) and the discharge vessel melt (2; 11) into the pearl (8; 15) and a device for switching off the lamp at the end of its life consisting of a paste (9; 18) which contains a metal hydride and is attached to the pearl (8; 15) characterized in that the pearl (8; 15) consists of a glass material that has a specific electrical resistance of greater than 10 ⁸ Ωcm at 350 ° C. the paste (9; 18) with the metal hydride is applied to the bead (8; 15) with respect to the heat radiation emanating from the filament (7; 13) during operation and during filament preheating in the radiation shadow the paste (9; 18) has no electrical contact with the power supply wires on the pearl (8; 15). Low-pressure discharge lamp according to claim 1, characterized in that the pearl (8; 15) consists of a potassium barium silicate glass. Low-pressure discharge lamp according to Claim 1, characterized in that the bead (8) has a substantially circular-cylindrical or cylindrical shape, the axis of which is aligned transversely to the axis of the discharge vessel in this area, and the current leads (5, 6) near the two ends of the bead (8) are melted and the paste (9) with the metal hydride is applied to the part of the pearl (8) facing away from the coil (7) in the radiation shadow of the coil (7). Low-pressure discharge lamp according to claim 3, characterized in that the pearl has a circular diameter d in mm in the case of a substantially circular-cylindrical or cylindrical shape, which obeys the following empirical formula: d> 0.2026 xm + 1.7617 with m ≥ 2 where m is the required amount of the metal hydride paste in mg. Low-pressure discharge lamp according to claim 1, characterized in that the bead (15) has a mushroom-like shape, the cap (16) of the mushroom facing the filament (13) and the paste (18) with the metal hydride below the cap (16) in Radiation shadow of the coil (13) is attached. Low-pressure discharge lamp according to claim 1, characterized in that the next point of the pearl (8; 15) facing the gas-tight seal (2; 11) of the discharge vessel is at least a distance of 2 mm from the gas-tight seal (2; 11). Low-pressure discharge lamp according to claim 1, characterized in that the metal of the metal hydride in the paste (9; 18) consists of a metal from the group titanium, zirconium, hafnium. Low-pressure discharge lamp according to claim 1, characterized in that the metal of the metal hydride in the paste consists of a metal alloy from the group of the alloys titanium-zirconium, titanium-hafnium and or zirconium-hafnium. Low-pressure discharge lamp according to Claim 7, characterized in that the paste (9; 18) contains titanium hydride TiH ₂ as the metal hydride. Low-pressure discharge lamp according to Claim 9, characterized in that the paste (9; 18) contains, as metal hydride, titanium hydride TiH ₂ with an average grain size of greater than 50 µm. Low-pressure discharge lamp according to Claim 1, characterized in that the paste (9; 18) contains, in addition to the metal hydride, a rheological additive with a proportion of less than or equal to 50% by weight.

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