DE3417601A1 - Compact low-pressure discharge lamp - Google Patents

Abstract

In the case of a compact low-pressure discharge lamp (19) having a base (26) which holds the ends of the wound discharge vessel (21), in order to create a cool point for the vertical operation of the lamp (19) with the base (26) located at the bottom, one or more separating elements (23) are arranged between the ends of the discharge vessel (21) and an adjacent tubular section. The discharge vessel (21) is surrounded by an enveloping bulb (20) which is mounted on the base (26) and has one or more ventilation openings at the end (27) facing away from the base (26). The enveloping bulb (20) additionally has one or more ventilation openings (28, 29) on the circumference, close to the end on the base side. As a result of these measures, luminous flux fluctuations are avoided and a maximum luminous flux emission from the lamp is achieved even during vertical operation with the base located underneath. <IMAGE>

Description

Compact low pressure discharge lamp

The invention relates to a compact low-pressure discharge lamp with a coiled tubular discharge vessel that has two outer sealed ends each with an electrode and a filling made of mercury and contains at least one noble gas and with one the outer ends of the discharge vessel receiving base, the discharge vessel for vertical operation of the lamp with the base at the top and the horizontal operation of the lamp with the side located base in a tube section of the discharge vessel remote from the base has a cooling point which determines the mercury vapor pressure and the discharge vessel also has at least one pipe section which is close to one or the two outer ones the tube ends carrying the electrodes and has a region which remains free from discharge.

From DE-OS 30 11 382 a discharge vessel for a compact Low-pressure discharge lamp known, which consists of several parallel to each other composed of straight pipe parts, the tubular through transverse to these parts Coupling parts are connected to one another. The coupling parts run in one certain distance from the respective ends of the longitudinal tube parts, so that the completed Pipe ends cannot be reached by the discharge. When the lamp is in operation, it forms in such a pipe end remote from the base, a cooling point where the mercury the lamp filling condenses.

Next is from DE-OS 31 12 878 and from the utility model application G 83 33 920.5 a low-pressure discharge lamp capped at one end is known at which the discharge vessel consists of a single or multiple U-shaped tube or consists of several U-shaped bent pipe parts. The U-shaped bends have essentially right-angled corners through which the discharge does not flow will. When the lamp is in operation, one of the base and electrodes is used remote corner of the discharge vessel as a cooling point where the mercury condenses.

The temperature of this coldest point of the discharge vessel sets When the lamp is in operation, it determines the mercury vapor pressure, which in turn determines the luminous flux output certainly.

Have the compact low pressure discharge lamps of the above applications in vertical operation with the base at the top as well as in horizontal operation with the base on the side an optimal temperature of the cold spot of about 45 OC and therefore show a quiet burning behavior with a constant maximum Luminous flux output.

However, in vertical operation with the base at the bottom the overhead cooling points in the pipe section removed from the base one of the optimal temperature deviating higher temperature of about 60 Oc, so that the luminous flux emitted by the lamp is reduced. It can also cause dripping of the mercury condensed at the cold spots and thus to fluctuations in the Luminous flux output come. This is the case with a correspondingly shaped discharge vessel possible that the condensed mercury directly on one of the two electrodes drips and thus leads to permanent damage to the same. The dripping mercury can, in unfavorable cases, also lead to the erosion of fluorescent material.

The aim of the invention is therefore to achieve a maximum luminous flux output of the compact low-pressure discharge lamp in every burning position, i.e. also in the vertical To ensure burning position with the base located below. In addition, the The latter burning position prevents condensed mercury from dripping down and so fluctuations in the luminous flux and possibly

damage to the electrodes can be avoided.

The compact low-pressure discharge lamp with the The main claim mentioned features is characterized according to the invention in that between the outer tube ends of the discharge vessel and carrying the electrodes a pipe section adjacent to this pipe ends to create a cooling point one or more for the vertical operation of the lamp with the base at the bottom heat-insulating separators are arranged.

With the help of the separating elements, the neighboring Pipe section greatly reduced by the heat given off by the electrodes. There this pipe section has at least one area, which - as with those listed above Low-pressure discharge lamps -of the discharge is not filled, can there, in vertical operation with the base located below, the mercury vapor pressure Form a determining cold spot. The training of the "oldest body" in this Area is also favored by the fact that in vertical operation with the bottom Pedestal to the original cooling point located above strength Experiences heating up and is therefore warmer than the new one formed by the partitions Cold spot; because this cooling point with vertical operation with the base located below If there is also a depression in the discharge vessel, there is another drip mercury is no longer possible.

The separating elements can be straight or also curved, each depending the exact shape of the discharge vessel. It is also possible that the separating elements which fully encompass the ends of the discharge vessel carrying the electrodes. To a To strengthen the shielding of the heat, it makes sense to add the separating elements to be provided with a heat-reflecting surface.

For optimal operation of the compact low-pressure discharge lamp if the burning position is vertical and the base is at the bottom, it is - as mentioned above - In addition to moving the cold spot down, it is also important that this spot has a temperature at which due to the resulting mercury vapor pressure gives a maximum luminous flux. This can be done by surrounding the discharge vessel Reach with a envelope piston, which at the end facing away from the base or one has multiple vents. In addition, the envelope must also be close to the base-side End - if possible in the immediate vicinity of the pipe section to be cooled - have one or more ventilation openings. Instead of the latter Openings, the base can also have one or more ventilation openings that connected by channels to the cavity between the discharge vessel and the envelope bulb are.

Through the envelope and the openings below and above will a convection of the air along the discharge vessel is achieved. In vertical operation with the base located below is due to the convection through the below Openings in the envelope or base "cold" air is sucked in from the environment, which then strokes along the discharge vessel while slowly heating up at the same time and exits through the openings at the top of the envelope.

A desired temperature for the cold point can then be at given operating temperature of the lamp and ambient temperature by a corresponding Shape of the envelope and a corresponding size, shape and position of the ventilation openings to adjust.

In the case of a compact low-pressure discharge lamp with one in the base Housed conventional or electronic ballast is also make sure that the heat developed by this device through an insulation is kept away from the discharge vessel. Otherwise, such a heat release could result the cooling effect, which is achieved by the separating elements and the envelope piston, partially or be canceled completely.

The invention is illustrated in more detail with reference to the following figures.

FIG. 1 shows a partially sectioned side view of a low-pressure discharge lamp without enveloping bulb FIG. 2 shows a plan view of a lamp corresponding to FIG 1 Figure 3 shows a partially sectioned side view of a Low-pressure discharge lamp with envelope bulb Figure 4 shows a partially sectioned Side view of a further embodiment of the low-pressure discharge lamp with a tubular envelope In Figures 1 and 2, a low-pressure discharge lamp 1 is shown without envelope. The discharge vessel 2 is composed of two U-shaped bent glass tubes 3, 4 from 12 mm outer diameter together, the two parallel to each other at a distance of 3 mm Have running longitudinal pipe sections of 105 mm in length. At the ends are those Glass tubes 3, 4 sealed by pinches 5, 6, with one pinch in each case 6 each tube 3, 4 carries an electrode 7, 8.

The two U-shaped glass tubes 3, 4 are aligned so one behind the other arranged that the two pinches 6 with the electrodes 7, 8 on the same Side lying. By means of a cross-melt 10 forming a passage 9 close the two pinches 5 without electrodes, the glass tubes 3, 4 are simple to one connected discharge path. Resulted from this type of connection above the bruises 5 sinks 11, which remain free from the discharge.

Between the two ends of the longitudinal tube sections carrying the electrodes 7, 8 and the two ends of the longitudinal pipe sections connected by the transverse fusion 10 a flat heat insulating separator 12 is attached to the bracket 13 of the discharge vessel 2 is connected. The separating element 12 with one Thickness of 1 mm is made of temperature-resistant heat-insulating plastic with metallized surface with high radiation reflection and is approx. 25 mm high and approx. 30 mm wide. With the help of this separating element 12 results in vertical operation of the low-pressure discharge lamp 1 with the base 14 lying below in the depressions 11 a Temperature of about 55 ° C.

This is the temperature of this pipe section - in this operating mode - Below the temperature of the substantially right-angled corners 15, 16 of the U-shaped Bend that forms the cold spot in the other burning positions. The mercury condenses thus in vertical operation with the base 14 located below in one of the two Lower 11 and forms a precipitate 17, the vapor pressure of which is the luminous flux of the Lamp 1 determined.

The low-pressure discharge lamp 1 has a G 23 base 14, the Upper part 18 for better holding the ends of the longitudinal tube sections of the glass tubes 3, 4 includes. A starter and a radio interference suppression capacitor are also integrated in the base 14.

FIG. 3 shows a low-pressure discharge lamp 19 with an envelope bulb 20 shown. The structure of the discharge vessel 21 corresponds to that in FIGS. 1 and 2. Here, too, there is between the two ends of the longitudinal tube sections carrying the electrodes 22 and the two ends of the longitudinal pipe sections connected by the transverse fusion a flat, heat-insulating separating element 23 is attached, which is also attached to the discharge vessel holder 24 is connected and has the same dimensions as described in FIGS. In addition, the discharge vessel 21 extends from a cylindrical envelope bulb 20 clear plastic with a Inside diameter of 50 mm and a wall thickness of 1.5 mm. The envelope piston 20 is at one end 25 connected to the base 26, while the other end 27 is completely open. At the extent If the envelope bulb has two opposite round ventilation openings at the level of the electrodes 22 28, 29 of 15 mm in diameter, with an opening exactly opposite the to cooling sink 30 is located.

With the help of the envelope 20 and the air convection achieved with it along the discharge vessel 21 occurs in the depression 30 to be cooled in the case of vertical Operation of the discharge lamp 19 with the base 26 located below a temperature of approx. 45 OC. The temperature of this pipe section is therefore not just one Relocation of the "oldest point" in the discharge vessel 21 to this pipe section result, but it turns out to be the "coldest point" due to this temperature - and thus also the temperature of the mercury 31 condensed there - also at vertical operation with the base at the bottom an optimal mercury vapor pressure one that enables maximum light output.

The low-pressure discharge lamp 32 in FIG. 4 is essentially correct corresponds to the lamp 19 shown in FIG. Here, however, the envelope piston points 33 does not have any ventilation openings at the level of the electrodes 34. The air flow arrives in this low-pressure discharge lamp 32 by two diametrically opposed circular openings 35, 36 in the upper base part 37 and via channels 38, 39 with a circular cross-section of 7 mm in the space between envelope piston 33 and Discharge vessel 40, the end of the channel 38 in the immediate vicinity the sink 41 to be cooled ends. Here, too, results for the cooling point in this Pipe off cut with vertical operation and the base below 42 a temperature of approx. 45 OC, which results in maximum light output.

- blank page -

Claims (5)

Claims (1). Compact low pressure discharge lamp (1, 19, 32) with a wound tubular discharge vessel (2, 21, 40), the two outer sealed Has ends each of which carries an electrode (7, 8; 22; 34) and that has a filling of mercury and at least one noble gas as well as with one the outer Ends of the discharge vessel (2, 21, 40) receiving base (14, 26, 42), wherein the discharge vessel (2, 21, 40) for the vertical operation of the lamp (i, 19, 32) with the base (14, 26, 42) at the top and the horizontal operation of the lamp (1, 19, 32) with laterally located base (14, 26, 42) in one of the base (14, 26, 42) removed tube section (15, 16) of the discharge vessel (2, 21, 40) has the cooling point that determines the mercury vapor pressure and the discharge vessel (2, 21, 40) also has at least one pipe section (11, 30, 41) which is close to a or the two outer tube ends carrying the electrodes (7, 8; 22; 34) and which has an area which remains free from the discharge, characterized in that, that between these outer pipe ends and such an adjacent pipe section (11, 30, 41) to create a cold spot for vertical operation of the lamp (1, 19, 32) with the base (14, 26, 42) below, one or more heat-insulating Separating elements (12, 23) are arranged. 2. Compact low-pressure discharge lamp according to claim 1, characterized in that that the heat-insulating separators have a heat-reflecting surface. 3. Compact low-pressure discharge lamp according to claim 1, characterized in that that the discharge vessel (21, 40) is surrounded by an envelope (20, 33) which is attached to the base (26, 42) and at the end facing away from the base (26, 42) (27) has one or more ventilation openings. 4. Compact low-pressure discharge lamp according to claim 3, characterized in that that the envelope (20) near the base-side end on the circumference one or more Has ventilation openings (28, 29). 5. Compact low-pressure discharge lamp according to claim 1 and 3, characterized characterized in that the base (42) has one or more ventilation openings (35, 36) which through channels (38, 39) with the cavity between the discharge vessel (40) and envelope piston (33) are connected.