DE4117288A1 - HIGH VOLTAGE IGNITION TRANSMITTER FOR IGNITING AND OPERATING AC HIGH PRESSURE GAS DISCHARGE LAMPS IN MOTOR VEHICLES - Google Patents

Description

The invention relates to a high-voltage ignition transformer for igniting and operating AC high pressure Gas discharge lamps in motor vehicles, with a core, with a primary winding surrounding the core, which consists of a There is film and with a surrounding the core Secondary winding, which consists of a film, wherein between the individual layers of the primary winding and the Secondary winding an insulating film is arranged.

From European patent application 03 91 470 A1 is a High voltage ignition transformer for igniting and operating High-pressure gas discharge lamps known Primary winding and its secondary winding from a film is wrapped. The material of the core of the The high-voltage ignition transformer consists of air.

The embodiment shown relates to a High pressure gas discharge lamp for use in the home, wherein the high pressure gas discharge lamp a socket for Screwing into commercially available lights. The Windings of the high voltage ignition transformer are on that End part of the glass bulb of the lamp coiled. Such a trained high voltage ignition transformer is for the Not suitable for use in motor vehicles, firstly the high pressure gas discharge lamps used in the home and differ in the motor vehicle sector and secondly the dimensions with the achievable efficiency below Use of an air core and the necessary Dielectric strength in the previously known embodiment are too large for an application in the motor vehicle. this applies especially because when igniting  High pressure gas discharge lamps in motor vehicles Ignition voltages of the order of 20 KV are required and the high-voltage ignition transformer at the Generation of such high voltages from the on-board voltage of a motor vehicle with the highest possible efficiency dimensions as small as possible and as high as possible Dielectric strength must have.

The invention is therefore based on the object High voltage ignition transformer for AC High pressure gas discharge lamps in motor vehicles too create a current-independent secondary inductance has the smallest possible dimensions and a simple one with the highest possible efficiency and inexpensive, high-voltage-compatible winding structure Has.

The object is achieved in that the Core is designed as an elongated core that the stretched core made of a soft magnetic ferrite Material exists and that the core has a cross-sectional area and the secondary winding has a number of turns the core is unsaturated in all operating conditions.

It is advantageous for the core to be an elongated core is formed because it is simple and inexpensive Way due to the large shear of the ferrite core Secondary inductance of the high-voltage ignition transformer can be dimensioned almost independent of current and thus Irregularities in the operating current, e.g. B. the Regulation of a constant light output complicate than sudden changes in the large starting currents are also safe and can be reliably avoided because the core is not can go into saturation. There is also the advantage that the high-voltage ignition transformer as low as possible Can have dimensions and a puncture-proof  high-voltage-compatible winding structure with one if possible high efficiency is achieved.

In this context, it is advantageous that the stretched core made of a soft magnetic ferrite Material is made, which makes the dimensions particularly small can be, and with a high voltage Winding structure the greatest possible efficiency for the High voltage ignition transformer can be achieved.

The advantages mentioned above are particularly then reached when the core has a cross-sectional area and the Secondary winding has a number of turns at which the core is unsaturated in all operating conditions.

Because the core is made of a high-resistance there is soft magnetic ferrite material Advantage that the eddy current losses in the ferrite core can be kept as small as possible.

It is advantageous that the primary winding on the Secondary winding is wound up because of this Primary winding completely encloses the secondary winding and thus the best possible magnetic coupling the primary winding with the secondary winding, which has a high degree of efficiency and secondly that Advantage that the lower potential in the operation of the High voltage ignition transformer on the outside of the High-voltage ignition transformer is present, resulting in a Simplified better insulation and thus higher security against rollovers.

In this context, it is particularly advantageous that the primary winding and the secondary winding each one Have one turn per layer of the film because it is very high winding tension is also the layer tension, which is isolated by the insulating film and the  Primary winding even with a minimum number of turns automatically even across the entire winding width is distributed so that there is an optimal coupling between the primary winding and the secondary winding and partial saturation of the ferrite core avoided will.

It is advantageous that the between the individual layers arranged the primary winding and the secondary winding Insulating film is wider than the film of the primary winding and the secondary winding because one simple and inexpensive construction a particularly high Security against rollovers results.

There is a between the secondary winding and the core Coil bobbin made of insulating material because that direct winding on the core complex and difficult is.

It is advantageous that the core is a rod core, which makes a particularly simple and inexpensive Embodiment results in which no saturation of the soft magnetic ferrite core occurs.

The same advantages also result from one advantageous form for the application of the foils as Primary winding when the core is cylindrical is.

Because the core supports the windings shoulders has the advantage that the field lines are not stretched so far from the end areas of the soft magnetic ferrite core emerge like one straight core that does not have such shoulders, causing eddy current losses in adjacent metal parts, such as B. a housing can be reduced.  

The same advantages arise when the core is one Roll core is.

It is advantageous that the core is the bobbin Primary winding and the secondary winding in one insulating potting compound are shed because the Risk of rollovers is reduced to a minimum and safety and lifespan are increased.

Because the core, the bobbin, the primary winding and the secondary winding is arranged in a housing and are shed with this, there is the advantage that the High-voltage ignition transformer a particularly compact, high-voltage-resistant, easy-to-assemble component.

An embodiment of the subject of the invention is in the drawings and is based on the following of the drawings described in more detail. Same or equivalent components of the subject matter of the invention are in provided all figures with the same reference numerals.

Show it

Fig. 1 shows a longitudinal section through a high-voltage ignition transformer,

Fig. 2 shows a cross section through a high-voltage ignition transformer,

Fig. 3 shows the detail H in accordance with Fig. 1 in an enlarged scale;

Fig. 4 shows an embodiment of the winding structure.

Fig. 1 shows a longitudinal section through a high-voltage ignition transformer. The stretched core (K) made of soft magnetic ferrite material, which is designed here, for example, as a rod core, is surrounded by a coil former (U), which consists of insulating material. The secondary winding (S) of the high-voltage ignition transformer, which consists of a conductive film (F) and an insulating film (I), is wound onto the coil former (U). The primary winding (P), which also consists of a conductive film (F) and an insulating film (I), is wound onto the secondary winding (S). The primary winding (P) and the secondary winding (S) are connected here by way of example to electrical connection elements (A) for the electrical connection. The contacting of the electrically conductive film (F) with the electrical connection elements (A) is not shown here and can, for. B. are made in the foils or welded to these connections.

The core (K), the coil former (U), the primary winding (P) and the secondary winding (S) are exemplary here Improve the flashover resistance in an insulating Potting compound (V). In addition, the core (K) is the Coil former (U), the primary winding (P) and the Secondary winding (S) here as an example in a housing (G) arranged and shed with this. Another one The high-voltage ignition transformer can be used as an exemplary embodiment also with other components of an igniter High pressure gas discharge lamp in an insulating Potting compound (V) should be shed.

Fig. 2 shows a cross section through a high-voltage ignition transformer. As already described under Fig. 1, the high-voltage ignition transformer here consists, for example, of a core (K), a coil former (U), a primary winding (P) and a secondary winding (S) using film technology, which with their electrical connection elements (A) , two of which are shown here by way of example, are cast by means of an insulating casting compound (V) in a housing (G).

The embodiment shown in Fig. 1 and Fig. 2 has particularly small dimensions and is particularly high voltage resistant with a simple and inexpensive design. When using a cylindrical rod core (K) shown here by way of example, the length of the housing is, for example, approximately 2 to 3 cm and the width and height of the housing is, for example, approximately 1 to 2 cm. In other exemplary embodiments, these dimensions can also be larger or smaller. In the high-voltage ignition transformer shown here for igniting and operating high-pressure gas discharge lamps in motor vehicles, which has to generate up to 20 KV from a few 100 volt ignition voltages, the secondary winding (S) applied to the inside of the coil former (U) has, for example, about 100 turns and has the primary winding (P) applied to the secondary winding (S), for example, about 4 turns. For good magnetic coupling, which achieves a high degree of efficiency, one turn per layer is applied when the film (F) is wound. Because of the extremely thin film (F) used for the windings (P, S) and the small number of turns of the primary winding (P), the primary winding (P) is not shown separately in all figures.

Fig. 3 shows the detail (H) corresponding to Fig. 1. The core (K) here consists of a soft magnetic ferrite material. In order to keep eddy current losses as low as possible, a material that is as high-resistance as possible is used here as an example. The coil former (U) surrounds the core (K) in such a way that the core (K) and the coil former (U) lie firmly against one another. In order to achieve the highest possible packing density and small dimensions, the secondary winding (S) is firmly wound on the bobbin (U). The primary winding (P), which is not shown in FIG. 3, is firmly wound onto the secondary winding (S). In another exemplary embodiment, the core (K) can have shoulders which support the windings (P, S) and which do not allow the field lines at the free ends of the core (K) to emerge as far as in the case of a straight core (K) without such shoulders. A particularly favorable embodiment of the core (K) results when using a roller core. Designs of this type are not shown in the figures.

Fig. 4 shows the winding structure of both the primary winding (P) and the secondary winding (S). Each layer of the primary winding (P) and the secondary winding (S) consists of an electrically conductive film (F), which is insulated from the other layers by an insulating film (I). As can be seen from FIG. 4, the width of the film (F) here is, for example, approximately 2/3 of the width of the insulating film (I) in order to avoid rollovers with great reliability. In the exemplary embodiment shown here, the width of the insulating film corresponds to the length of the cylindrical core (K) in order to avoid rollovers as best as possible. With the winding of the primary winding (P) and the secondary winding (S) there is one turn per layer, which ensures a very good magnetic coupling while avoiding saturation zones of the core (K), even if the primary winding (P) only a few Has turns. The insulating film (I) consists here, for example, of a plastic material and, for example, has a thickness of approximately 15 μm. The film (F), from which the primary winding (P) and the secondary winding (S) are made, can be made of copper or aluminum, for example, and can have a thickness of about 10 µm, for example. Depending on the application and the requirements, these dimensions can be larger or smaller.

Reference symbol list

(A) connection elements
(F) foil
(H) detail H
(I) insulating film
(K) core
(G) housing
(P) primary winding
(S) secondary winding
(U) bobbin
(V) potting compound

Claims (12)

1. High-voltage ignition transformer for igniting and operating AC high-pressure gas discharge lamps in motor vehicles, with a core (K), with a core (K) surrounding the primary winding (P), which consists of a film (F) and with one Secondary winding (S) surrounding the core (K), which consists of a film (F), an insulating film (I) being arranged between the individual layers of the primary winding (P) and the secondary winding (S), characterized in that the core ( K) is designed as an elongated core (K), that the elongated core (K) consists of a soft magnetic ferrite material and that the core (K) has a cross-sectional area and the secondary winding (S) has a number of turns, in all operating conditions the core (K) is unsaturated. 2. Ignition transformer according to claim 1, characterized in that the core (K) from a high impedance there is soft magnetic ferrite material. 3. Ignition transformer according to claim 1 or claim 2, characterized in that the primary winding (P) the secondary winding (S) is wound up. 4. Ignition transformer according to claim 3, characterized in that that the primary winding (P) and the secondary winding (S) each have one turn per layer of the film. 5. Ignition transformer according to claim 4, characterized in that that between the individual layers of the primary winding (P) and the secondary winding (S) arranged Insulating film (I) is wider than the film (F) Primary windings (P) and the secondary winding (S). 6. Ignition transformer according to claim 5, characterized in that  that between the secondary winding (S) and the core (K) a coil former (U) made of an insulating material is arranged. 7. Ignition transformer according to claim 6, characterized in that that the core (K) is a rod core. 8. Ignition transformer according to claim 7, characterized in that that the core (K) supports the windings (P, S) Shoulders. 9. Ignition transformer according to claim 8, characterized in that that the core (K) is cylindrical. 10. Ignition transformer according to claim 9, characterized in that the core (K) is a roller core. 11. Ignition transformer according to at least one of the above Claims, characterized in that the core (K), the bobbin (U), the primary winding (P) and the Secondary winding (S) in an insulating potting compound (V) are shed. 12. Ignition transformer according to claim 11, characterized characterized in that the core (K), the coil former (U), the primary winding (P) and the secondary winding (S) in arranged in a housing (G) and cast with it are.