EP0131222A1 - Choke for obtaining high magnetic-induction rates - Google Patents

Abstract

In a choke for operation at a mains frequency of 50 or 60 Hz, and for the generation of flux densities greater than 0.8 Teslas, the ferromagnetic core (10) is designed as an annular hollow cylinder in whose cavity (18) is located the complete insulated copper winding (19). The annular hollow cylinder of the core (10) forms a circuit and has a rectangular cross-section. Additionally, it has one or more air slots (15, 16) which extend over the complete annulus of the hollow cylinder, and a separating gap, so that the annulus is not completely closed. The choke, with low power loss, has a very compact construction and is used as a ballast for a compact low-pressure discharge lamp, particularly for installation in a socket or in an adapter. <IMAGE>

Description

The invention relates to a choke with a ferromagnetic core and an insulated copper winding for operation with 50 or 60 Hz mains frequency and for generating flux densities greater than 0.8 Tesla.

The chokes with ferromagnetic core material known from the literature for producing large flux densities usually have a U-shaped or E-shaped core, which is closed by an I-shaped yoke. Chokes of this type have unfavorable construction data because they take up a lot of space and have large power losses. In this case, the iron path of the core is relatively long, so that a lot of energy is required for the magnetization of the ferroma grit. Such a choke has a magnetization curve with a large saturation range. In addition, chokes designed in this way usually have very large end windings which, since they are located outside the core, have no magnetic effect and thus likewise lead to high power losses of the choke. The copper wire expenditure for the formation of such winding heads can in this case amount to 30 to 40% of the total wire expenditure required for the choke.

On the other hand, it is known to use F _err it _k er _ne in the form of shells or bells at medium and high frequencies, as a result of which large iron paths and end windings can be largely avoided. With this core material, however, the largest possible Outside diameters of at most 50 mm can only achieve flux densities with values less than 0.5 Tesla. Larger cores, which could possibly be used to achieve higher flux densities, cannot be produced because the core material is very brittle and the risk of breakage then becomes too great.

The aim of the invention is to create a throttle that is as compact as possible, with small losses and with the least material expenditure, with which flux densities greater than 0.8 Tesla can be achieved in the case of mains operation. In addition, the choke should be usable as a ballast for low-pressure discharge lamps, in particular those with compact dimensions, and fit into the base or into the adapter for such a lamp.

The choke with the features mentioned in the preamble of the main claim is characterized according to the invention in that the core is designed as an annular hollow cylinder, the entire copper winding being located in the cavity of the core.

A core designed in this way creates a very compact choke with a short iron path, which has a relatively straight-line magnetization curve. The choke has no winding heads, so that the power losses caused by the winding can be reduced from the otherwise usual 30 to 50% to less than 5%.

The circle has proven to be the cheapest form for the ring-shaped core of the choke, since such a form is most versatile. However, it is also possible to give the ring the shape of an oval, a rectangle or a polygon - depending on the required for the possible installation - to give, without thereby changing the characteristics of the throttle significantly.

The ring-shaped hollow cylinder of the core advantageously has a rectangular cross section, which - as shown in the second exemplary embodiment - results in a very simple production method for the core. Due to the right-angled boundaries of the core, there are also no dead spaces during installation that remain unused.

The core has one or more air slots that extend over the entire ring shape and extend from the cavity located in the center of the core to the outside. These air slots ensure extensive linearization of the magnetization characteristic, so that the characteristic only reaches the saturation range at high field strengths.

The annular core has a separation gap, so that the ring shape is not completely closed. This largely suppresses eddy currents in the core and thus reduces the losses of the choke. The separation gap also serves to lead the ends of the copper winding out of the cavity of the core.

The choke is intended in particular as a ballast for a compact low-pressure discharge lamp and is mounted in the base of such a lamp. However, there is also the possibility of inserting the series choke into the housing of an adapter, the latter having a socket for receiving a lamp base and a socket for inserting the adapter into a standardized luminaire socket. With help Such an adapter makes it possible to operate a compact low-pressure discharge lamp on a standardized socket for an incandescent lamp.

Due to its ring shape, the choke can be used very well in the adapter so that it surrounds the socket for receiving a lamp base in a ring. This space-saving attachment also makes it possible to use the throttle as a supporting part of the adapter on which the other components are suspended. The choke only needs to be protected from contact by e.g. thin-walled insulation plastic layer.

• Figur 1 zeigt ein Ausführungsbeispiel der erfindungsgemäßen Drossel
• Figur 2 zeigt ein weiteres Ausführungsbeispiel der erfindungsgemäßen Drossel
• Figur 3 zeigt einen Sockel einer kompakten Niederdruckentladungslampe mit einer integrierten erfindungsgemäßen Drossel
• Figur 4 zeigt einen Adapter für eine kompakte Niederdruckentladungslampe mit einer integrierten erfindungsgemäßen Drossel

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

• Figure 1 shows an embodiment of the throttle according to the invention
• Figure 2 shows a further embodiment of the throttle according to the invention
• Figure 3 shows a base of a compact low-pressure discharge lamp with an integrated choke according to the invention
• FIG. 4 shows an adapter for a compact low-pressure discharge lamp with an integrated choke according to the invention

FIG. 1a shows a top view and FIG. 1b shows a section through an exemplary embodiment of the throttle according to the invention. In the construction based on the classic construction of a throttle the core 1 is composed of U-shaped sheet-metal pieces 2, 3 with a thickness of 0.5 mm, two sheet-metal pieces 2, 3 lying opposite each other with their openings and forming an air slot ₇ 4 of 0.3 mm, which is provided with a press chip - Plastic mass is filled. The pairs of sheet metal pieces 2, 3 are arranged in the form of a circle which is not completely closed and has a separation gap 5 of 2 to 4 mm in width. In the cavity 6 formed by the U-shaped sheet metal pieces 2, 3, which is designed with an insulating plastic film - not shown - is the copper winding 7, the ends 9 of which are led out through the separation gap 5.

FIG. 2a shows a top view and FIG. 2b shows a section through a further exemplary embodiment of the throttle according to the invention, the manufacture of which is simplified compared to the exemplary embodiment from FIG. The circular core 10 with a rectangular cross section is composed here of the side plates 11, 12 with a thickness of 0.5 mm - 6 plates on the outside and 7 plates on the inside, so that approximately the same amount of magnetization results - as well as on the ring plates 13, 14 above and below - 7 sheets each - together. Between the innermost annular plates 13, 14 above and below and the side plates 11, 12 there are air slots 15, 16 of 0.12 mm each, which are filled with a pressboard plastic compound. All side or circular ring plates 11, 12, 13, 14 are not completely closed, but form an annular core with a separation gap 17 of 2 to 4 mm in width. In the cavity 18 formed by the side or annular plates 11, 12, 13, 14 and which is designed with an insulating plastic film (not shown), there is the copper winding 19, the ends 20, 21 of which are led out through the separation gap 17.

In both embodiments, the core has an outer diameter of 71 mm, an inner diameter of 44 mm and a height of 28 mm. In the cavity of the 21 x 6 mm core made of dynamo sheet, there is a winding made of 1700 turns of single-coated wire with a wire diameter of 0.24 mm. A choke according to the second embodiment has a flux density of 1.1 Tesla at 180 V operating voltage and a current of 200 _m A. The power loss of the choke amounts to about 4.5 V. The flux density of the first exemplary embodiment is somewhat lower with the same operating voltage and the same current and has a higher power loss due to the numerous air slots on the outer radius due to the structure.

FIG. 3 shows the base 22 of a compact low-pressure discharge lamp. The throttle 23 surrounds the pinch 24 of the outer vessel 25 in a circle and is electrically connected to the screw thread 29 of the base 22 via the two electrodes 26, 27 and the starter 28. The discharge runs from the electrode 26 through the curved - not shown - tubular inner vessel 30, the outer vessel 25 and the bent - not shown - tubular inner vessel 31 back to the electrode 27.

FIG. 4 shows an adapter 32 for connecting a compact low-pressure discharge lamp to a standard incandescent lamp holder. The housing 32 of the adapter has a socket 33 for receiving the lamp base and a screw base 34 for inserting the adapter into a standard incandescent lamp holder. The throttle 35 in the housing 32 surrounds the socket 33 in a circle and at the same time represents the support member for the entire adapter.

Claims (9)

1. Choke with ferromagnetic core (1, 10) and an insulated copper winding (7, 19) for operation with 50 or 60 Hz mains frequency and for generating flux densities greater than 0.8 Tesla, characterized in that the core (1 , 10) is designed as an annular hollow cylinder, the entire copper winding (7, 19) being located in the cavity (6, 18) of the core (1, 10). 2. Choke according to claim 1, characterized in that the annular core (1, 10) forms a circle. 3. Choke according to claim 1, characterized in that the annular hollow cylinder of the core (1, 10) has a rectangular cross section. 4. Choke according to claim 1, characterized in that the core (1, 10) has one or more air slots (4; 15, 16) which extend over the entire ring shape of the core (1, 10) and of which in the center of the core (1, 10) located cavity (6, 18) extend to the outside. 5. Choke according to claim 1, characterized in that the annular core (1, 10) has a separation gap (5, 17), so that the ring shape is not completely closed. 6. Choke according to claim 5, characterized in that the ends (8, 9; 20, 21) of the copper winding (7, 19) through the separation gap (5, 17) from the cavity (6, 18) of the core ( ₁ , 10) are brought out. 7. discharge lamp with a base (22), characterized in that a choke (23) according to one or more of claims 1 to 6 is contained in the base (22) as a ballast for the discharge lamp. 8. Adapter for a discharge lamp with a housing (32), which has a socket (33) for receiving a lamp base and a socket (34) for inserting the adapter into a standardized light socket, characterized in that in the housing (32) as a ballast a choke (35) for the discharge lamp is included according to one or more of claims 1 to 6. 9. Adapter according to claim 8, characterized in that the core of the throttle (35) surrounds the socket (33) for receiving a lamp base in a ring.

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