NL8205079A - LOW-PRESSURE GAS DISCHARGE LAMP, IN PARTICULAR FLUORESCENT LAMP FOR SMALL POWER. - Google Patents

Description

* --3 VO 3971

Title: Low pressure gas discharge lamp, in particular low power fluorescent lamp.

The invention relates to low-pressure gas-discharge lamps, more particularly low-pressure gas-discharge lamps, which are provided with a connection base on one side and which are designed in a compact form.

Fluorescent lamps with parallel arranged rod-shaped tube parts which are connected to each other by means of an arc-shaped part or another permeable connection are known from DE-PS 858 105; DE-OS 30 11 382; and DE-OS 30 11 383. With all these three known techniques it is intended to form a cooling zone whereby the partial mercury pressure in the relevant Tamp is stabilized. This is achieved according to these known techniques, so that the ends of each rod-shaped tube section above the connection point are not involved in the gas discharge. The drawback of the geometry of such a construction is that these tube sections, which act as cooling regions, make only a small contribution to the light output. Another drawback is that the area of the cooling area must remain relatively small in order to obtain the largest possible surface area for the light output.

As a result, operation of the lamp with a high thermal load is only possible at the expense of a sharp decrease in the luminous efficiency.

The object of the invention is to control the partial metal vapor pressure or the partial mercury vapor pressure in low-pressure gas discharge tubes with an internal diameter d ^ (6 <d ^ <16) mm, such that in connection with an optimal conversion of supplied electric energy into metal or mercury resonance radiation, the critical mercury vapor pressure is not exceeded or only negligibly, no additional measures such as, for example, the formation of amalgam to control the metal or mercury vapor pressure are required.

The object of the invention is further to make the geometry of a discharge tube such that a cooling area with a large surface area is formed, without thereby reducing the light-emitting surface of the 8205079-2 discharge tube.

According to the invention this is achieved in that the distance between the electrodes and the ends of the tube is 2.0 to 4.0 times as great as the internal diameter of 6 to 16 mm of the rod-shaped parallel tube section of the discharge tube, however, said tubing section from the tubing ends to the electrodes is surrounded at least twice the internal diameter of the rod-shaped parallel tubing section of the discharge tube by a heat-dissipating sleeve. This sets, for example, a partial mercury vapor pressure of (1 - 2) Pa 10, which pressure is optimal, for example for internal pipe diameters of (8 - 12). Mm. This solution is particularly advantageous for lamps provided with a connection base, in which the lower ends must be carried stably and which ends do not contribute to the light output.

In further explanation of the invention, an exemplary embodiment thereof will be described below with reference to the drawing. The drawing (fig. 1) shows a fluorescent lamp with two parallel rod-shaped tube sections 6 and 7, the inner surface of which is covered with a fluorescent substance 8. The ends of the two tube sections 6 and 7 remote from the 20 electrodes are connected to each other via a discharge-permeable pad. At the other ends of the rod-shaped tube sections 6 and 7 are the electrodes 1 and 2, the distance between these electrodes and the associated tube section ends 3 and 4, 2.0 to 4.0 larger than the internal diameters of the respective rod-shaped tube sections 6 and 7. Those sections of the rod-shaped tubes 6 and 7 extending from the respective tube ends 3 and 4 over a distance up to three times greater than the internal diameter of these tubes is enclosed in this exemplary embodiment by a metal sleeve 9 (aluminum). The heat is dissipated from the outer walls and the rod-shaped tube sections 6 and 7 by direct contact with the metal sleeve 9 and, moreover, by a heat-dissipating mixture 10 consisting of 20% silicone rubber and 80% aluminum powder.

8205079

Claims (7)

Low-pressure mercury vapor discharge lamp, comprising two or more rod-shaped tube sections arranged in parallel, which are connected to one another via an arc-shaped part or by another discharge-permeable connection, characterized in that the distance between the respective electrodes (1, 2) and the respective tubular section ends (3, 4) is 2.0 to 4.0 times the internal diameter of the respective tubular sections; and in that the discharge tube portion extending from the respective end (3, 4) to the electrodes (1, 2), however, at least a distance from the respective end (3, 4) to twice the interior diameter of the respective rod-shaped tube (6, 7) in the direction of the electrodes (1, 2), is surrounded by a heat-dissipating sleeve. 2. Low pressure discharge lamp according to claim 1, characterized in that the heat-dissipating sleeve is formed from a mixture containing a binder or adhesive and a heat-conducting filling material. Low-pressure discharge lamp according to claims 1 or 2, characterized in that the mixture consists partly of silicone rubber and partly of aluminum powder or aluminum chips. 4. Low pressure discharge lamp according to one of the preceding con-. clauses, characterized in that the mixture contains 10-50% binder or adhesive and 50-90% heat-dissipating filling material. Low-pressure discharge lamp according to claim 1, characterized in that the heat-dissipating sleeve is in the form of a metal sleeve which is in direct contact with the surface of the respective discharge vessel. 6. Low-pressure discharge lamp according to one of the preceding claims, characterized in that the heat-dissipating sleeve consists of a metal sleeve which communicates with a mixture consisting of a binder or adhesive and a heat-dissipating filling dust. Low-pressure discharge lamp according to claim 1, characterized in that the distance between the respective electrodes (1, 2) and the desbe-8205079 * v - 4 striking vessel end (3,4) is preferably three times as great as the internal diameter of the respective rod-shaped tube section (6, 7) of the discharge vessel? and the electrodes (1, 2) comprise a dual winding or a triple winding with a tungsten core as the primary winding. 8205079