DE2601664B2 - Fluorescent lamp - Google Patents

Description

The invention relates to a fluorescent lamp with a translucent bulb with a ferrite core a winding for exciting the core with a high frequency magnetic field and an ionizable

Medium inside the piston, which is an electrical Discharge due to an in it through the ferrite core

induced electric field while maintaining

Radiation emitted, as well as a phosphor on the Inside of the bulb, which makes the radiation visible Transforms light The phosphor described in US-PS 35 21 120

Lamp of the above type has an annular piston which is attached to a rod-like ferrite core This type of construction has the consequence that the known fluorescent lamp generates a high-frequency magnetic field in the one surrounding the bulb during operation Contained air and thus represented an unpleasant source of electromagnetic radiation and interference.

The object on which the invention is based is to develop a fluorescent lamp of the type mentioned at the beginning Kind of creating in the case of the high frequency magnetic field is considerably reduced in the dcv environment of the piston and good heat dissipation from the ferrite core is ensured

According to the invention, this object is achieved in that the piston is essentially spherical in shape det is and the ferrite core is a closed loop forms and is partly inside and partly outside of the piston

Advantageous embodiments of the invention can be found in the subclaims.

Embodiments of the invention are shown in the drawing and will be described in more detail below described. It shows

Fig. 1 is a side view in section of an embodiment of the fluorescent lamp,

FIG. 2 a front view in section of the lamp according to FIG.

3 shows a partial side view of another exemplary embodiment of the fluorescent lamp,

Fig. 4 is a sectional front view of the lamp

* o according to fig. 3,

FIG. 5 is a view of the lamp structures according to FIG the F i g. 3 and 4,

6 shows a method for producing a lamp according to FIGS. 3, 4 and 5 and

F i g. 7 a full fluorescent lamp with a Power supply and a screw base.

In the embodiment shown in FIG. 1, there is a closed loop forming Ferrite core 12 partly inside and partly outside half of a bulb 11 of a fluorescent lamp. Of the evacuable, translucent bulb 11 (which can for example consist of glass) is with a gaseous ionizable medium 19, such as a mixture of noble gas and Hg, filled. He has one flat base area 11a with a rectangular slot 26a, in which the ferrite core 12 with a middle Winding space 30 is arranged, which, as in F i g. 2 is shown ring-shaped with a rectangular cross-section 18 can be formed and in an annular Metal container 24 is included. Because the Ferrite core 12 is partly inside and partly outside of lamp bulb 11, a smaller one protrudes Segment of the core 12 and the space 30 enclosed by it beyond the lamp bulb base 11a in FIG the free environment.

The interior of the lamp envelope 11 and the outer surfaces of the metal container 24, which are within the Lamp bulbs are covered with a phosphor 20

coated, the ultraviolet radiation of the gas absorber, can, which has cni generally a peak at approximately 2,537 · 10 ^5, and can emit after characterized carried excitation radiation within the visible spectrum, to provide a highly effective and pleasant lighting yield. The ionized gas therefore does not generate the light, but rather the radiation that causes the emission of light from a phosphor. This allows a relatively small input power into the ionizable gas. That section of the rectangular slot 26a that lies within the core winding space 30 is covered with a rectangular glass bridge 26 and sealed with this. On the winding space 30, there is a primary winding 17 around the. Metal container 24 wrapped around. A current from a high-frequency power source 16 flows through the winding 17 and excites the core with a magnetic field, which initiates ionization of the gaseous medium 19 and provides for an emission of visible light in the manner described above heat dissipating element 28 connected to the metal container 24. The heat transferred to this element 28 is given off to the free environment or to a suitable one. Radiator directed on a lamp base (not shown)

Details of the metal container 24 are shown in FIG. 2 The container can be made of copper, beryllium, aluminum or any other metal, that is compatible with the low pressure »atmosphere and for the absorption of the The phosphor 20 is suitable. The container 24 forms a smooth, uninterrupted jacket around the larger circumference of the ferrite core 18 around, but contains a gap around its smaller one Extends the main circumference and prevents a short circuit of the induced electric field An electric Isolation and maintenance of the vacuum across the gap is ensured by a glass seal 27 obtain. The container 24 can with a gas impermeable <* o Sigen glass layer 23 be coated in order to improve the adhesion of the phosphor 20.

Obviously, the choice of core material is an important factor in the operation of this lamp. That Ferrite material must be selected so that it is high Permeability and low internal heat loss at the operating frequency. As is known, is a Ferrite a ceramic-like material that is characterized by ferromagnetic properties and is common has a spinel structure with a cubic crystal lattice and that has the general formula MeFe2Ü4, where Me represents a metal atom.

It is necessary that the cores used be made of such a material and such Have configuration that the core losses are not greater than 50%, so that an effective coupling of the electromagnetic energy can be brought about in the light source. Decrease in a similar manner lower core losses heating up the core and lowering the possibility of destruction to an eo Minimum and bring the efficiency of the core to a maximum. Preferably the core losses held at less than 25% of total input power.

A high permeability core material is required to ensure adequate coupling of the high frequency energy with the gas with minimal electromagnetic radiation. A ferrite with a relative permeability of at least 2000 is advantageous. Suitable ferrites are available with these characteristics over the frequency range of 25 kHz to 1 MHz. High frequency operation is desirable from the standpoint of reducing ferrite loss; but the cost of currently available semiconductors for use in the high frequency power source 16 limits the maximum frequency at which a practical lamp can be operated to about 50 kHz. Particularly suitable is a material that cm- ³ at 10 ~ ⁵ Weber / cm is characterized by loss of less than 30 mW peak flux ² for operation at 50 kHz

In another exemplary embodiment, which is shown in FIGS. 3, 4 and 5, the ferrite core 12 is held by a tubular projection 11Z which extends from the liner base 11a The ferrite core 12 leads through two rectangular slots in the sides of the projection 116 and is attached to these through glass seals 27a A circular Abdekkung 29 is fixed (see also F i g. 6) encloses the top of the rectangular slits and is sealed with the projection IXb and the inner surface of the ferrite core 12th

The outer circumference of the ferrite core 18 is wrapped with a flat metal band 25, which carries the core and supports the dissipation of the heat generated therein be coated in order to facilitate the inclusion of the phosphor 20 and the seal with the cover 29 and the projection 11 b .

As in the previously described embodiment, a primary winding 17 around the ferrite core 18 and wrapped around the metal strip 25 and the inside enclosed by the portion of the core winding space 39, which is b within the projection 11 and is exposed to the outside atmosphere. A heat-dissipating element 28 made of metal is connected to the metal strip 25 on the inside of the projection 116 and serves to dissipate the heat from the core 18.

Further details of the lamp structure emerge from FIG. 6, which shows the lamp base Ma with the tubular projection Wb and the rectangular slots Hc. A disk-shaped glass cover 29 is shown prior to attachment to the projection 11.

Such a fluorescent lamp can be produced, for example, by first preforming the base part 11a made of glass with the tubular projection Hft and r> * n rectangular slots lic. The glass-coated ferrite core 12 with the winding 17 attached to it is inserted into the contactor lic and covered with a pane of glass 29. Upon heating of the glass-made projection 11 merges with b of the core layer be coated and the glass sheet 29 and forms the vacuum seals, which are shown in Figs. 2 and 3 at 27a. The upper part of the piston 11 is not shown in the above figures is then sealed with the Basistjil 11 a, the piston evakuziert and filled in an unusual manner with a gas. Alternatively, the winding 17 can be attached to the core 12 after the sealing process is complete

The construction of the glass / ferrite seals is required. It has been found that these seals can be made if in a known manner

the thermal expansion coefficient of the sealing glass is matched to that of the ferrite. It has been found that ferrites usable linear expansion coefficient of about 11 ■ 10 - have '/ ° C at 400 ⁰ C and a linear expansion depending on the temperature to 700 ° C. Many types of glass available have coefficients of expansion in this range. For example, the commercially available potassium / sodium carbonate / lead glass Type 1190 has a suitable Ausdehnungskoffiezienten of 12.4 · IO ⁶ / 'C and is a Ferriiabdichtung. This glass No. 1190 is usually also used for a seal against iron and is also suitable for a seal against beryllium, which has an expansion coefficient of 11.6 · 10 "V ⁰ C.

Fig. 7 shows a complete fluorescent lamp. A lamp base 13 which, for example , attaches an Edison oCi'iräüu.SCfCKct Sein KdTiM, iäi du uciVi a UMUC to a cylindrical base 14. The base 14 contains a suitable circuit 16 for high-frequency power supply and a ballast. The high-frequency power feed takes up network energy from the screw base 13 and transforms it into a high-frequency current which is fed to the ferrite core via the primary winding 17. A light-permeable, evacuable piston 11 is coated with a phosphor 20 and attached to a base part 14 opposite the base 13. The base of the piston 11 is closed by the base assembly 14 and carries üb a tubular projection, is mounted through which the ferrite core 12 a circular glass disc 29 covers the innermost end of the

in projection and is sealed with the ferrite core 12 and the projection 111>. A filling gas 19, which can for example be a mixture of mercury vapor and krypton, fills the piston and couples the ferrite core 12. The primary winding 17 couples the ferrite core 12 with numerous turns and lies within the projection lift. A heat-dissipating element 28 is with the ferrite core 12 within the Vuispi uiigci Ub vei UUIiUCIi Uhu uieni / Ui Αΰίυίιι of heat. The space within the projection Ub and the base assembly 14 can, if desired, be filled with a thermally conductive resin material (not shown) in order to further improve the heat dissipation from the core.

For this purpose 2 sheets of drawings

Claims (9)

Palent claims: 1. Fluorescent lamp with a translucent bulb, a ferrite core with a winding to the Exciting the core with a high frequency magnetic field and an ionizable medium within the piston, which creates an electrical discharge due to an electric field induced therein by the ferrite core and thereby Radiation is emitted, as well as a fluorescent substance on the inside of the bulb, which the radiation in converts visible light, characterized in that the piston (U) substantially Is spherical and the ferrite core (12) forms a closed loop and partially inside and partially outside of the piston (U) 2. Fluorescent lamp according to claim 1, characterized in that the ferrite core (12) with a gas impermeable glass material! (23), which is suitable for coating with a phosphor (20), is covered 3. Fluorescent lamp according to claim 1, characterized in that the core (12) sealed by a rectangular notched base part (Wa) ir. The bulb (U) enters and the core (12) has a substantially rectangular cross-section (18) 4. Fluorescent lamp according to claim 3, characterized in that a rectangular bridge element (26 "with the core (12) and the bulb (11) is sealed and covers the rectangular opening within the central space of the core (12). 5. fluorescent lamp according to claims 1-4, characterized in that the ferrite core (12) is ring-shaped and enclosed by an evacuable ring-shaped metal container (24) which forms an opening around its main inner periphery and a dielectric Contains material (27). 6. Fluorescent lamp according to claim 3, characterized in that the rectangular notches (HcJ of the base part (Wa) at the inwardly directed end of a tubular projection (116 ^ and the inwardly directed end of the tubular projection (1IbJ and the ferrite core (12 ) are sealed with a flat washer (29). 7th Fluorescent lamp according to claims 1-4, characterized in that the outer major periphery of the ferrite core (12) is of a flat one Metal tape (25) is surrounded and on the ferrite core (12) and the flat metal tape (25) a layer (23) is made of gas-impermeable glass-like material. 8. Fluorescent lamp according to claim 7, characterized in that the flat metal strip (25) consists of Made of copper or aluminum. 9. Fluorescent lamp according to claim 5 or 7, characterized in that a heat-dissipating element (28) is connected to the metal container (24) or the flat metal strip (25) within the tubular projection (Wb) of the base part (Wa)