DE2338925A1 - IGNITION COIL, IN PARTICULAR IGNITORS FOR MAGNETIC IGNITORS - Google Patents

Description

R. 16 OO

l6.7. 1973 Ws / Ma

Attachment to

Patent and utility model registration

Robert Bosch GmbH, Stuttgart Ignition coils, in particular ignition armatures for magneto igniters

The invention relates to an ignition coil, in particular an ignition armature for magneto igniters of internal combustion engines an iron core and an insulation body attached to it, which carries a primary and a secondary winding, wherein the beginning of the outer secondary winding consisting of several winding layers with the end of the Primary winding is connected in series and the end of the secondary winding has a high voltage connection for a Ignition cable carries.

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The secondary winding of the known ignition coils and armatures for internal combustion engines consists of very many turns of thin wire wrapped in layers with intermediate insulation. In her the Induced ignition voltage required to ignite the internal combustion engine. Depending on the design of the ignition coil a high-voltage pulse with a rate of rise of 500 V is generated with each ignition process up to 5 kV per ps to a voltage level of 10 kV up to 15 kV, which occurs within a few ns when the spark flashes on the electrodes of a spark plug collapses again.

These high-frequency voltage changes cause a different voltage stress on the individual Intermediate insulation of the various winding layers, experience has shown that especially the initial and The end positions of the secondary winding are subject to very high stresses. If the ignition coils failed determines that the voltage flashovers occurred at the beginning or at the end of the secondary winding.

To improve the dielectric strength of such high-voltage coils it is known to carry out the start and end positions with reinforced intermediate insulation and To reduce the layer tension, wrap the start and end positions in a locked manner. It has, however showed that such measures do not lead to a decisive improvement in the dielectric strength is to achieve.

The invention is based on the problem of surge voltage resistance of ignition coils and ignition armatures

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through a high voltage distribution that is as even as possible at all positions of the secondary winding when the ignition voltage occurs to trigger the ignition to improve significantly on internal combustion engines.

The invention is based on the knowledge that in the case of voltage pulses with a high rate of rise and fall, the voltage distribution on the end faces of the windings primarily from the capacities of the layers to one another and to ^ em to ground potential lying iron core is dependent or can be influenced by it.

A desired voltage distribution that relieves the load on the start and end positions of the secondary winding is achieved according to the invention achieved in that the capacitance of the start and end positions of the secondary winding is at least as large is like the capacity of the layers in between.

This ensures that when the high-frequency Ignition voltage pulses the start and end positions are no longer charged to a higher voltage than the layers lying between it. The ignition armatures and ignition coils according to the invention therefore have an extremely high Impulse withstand voltage.

An advantageous embodiment of the invention for increasing the capacitances at the start and end positions of the secondary winding is achieved in that an isolated, overlapped metal layer is arranged at the start and end of the secondary winding, which extends over at least part of the layer width of the secondary winding.

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Details of the invention in an ^exemplary: exemplarily. It shows:

Pig. 1 an ignition armature for a magneto with a Primary and secondary winding,

2 shows an equivalent circuit diagram of the layer capacitances and the spark plug spark gap,

Fig. 5 is a schematic representation of the initial position the secondary winding with a metal foil,

Fig. 4 shows the isolated overlap of this metal foil and

5 shows the end position of the secondary winding with a further one Metal foil.

The ignition armature denoted by 10 in FIG. 1 is part of a magneto (not shown) for internal combustion engines. It is located on an armature plate within a magnet generator driven by the internal combustion engine attached. It consists of a laminated iron core 11 with two pole pieces 12 for the entry and exit of the rotating one Pole wheel outgoing magnetic flux. On the iron core 11 is a coil frame 1? arranged from insulating material, which carries a primary winding 14 and a secondary winding 15. The primary winding 14 is directly on the Coil frame IJ wound. It consists of a few layers insulated wire 16, which in relation to the wire 17 (see Fig. 3) of the secondary winding 15 has a relatively large cross-section having. The outer one on the primary winding 15 arranged secondary winding 16 consists of many layers

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very thin, insulated wire 17, each insulated from one another by an intermediate insulation 19 made of paper are. Primary winding 1J5 and secondary winding 16 are electrically connected in series by the end of the primary winding wire 16 is connected to the beginning of the secondary winding wire 17 (Fig. 3). The end of the secondary winding wire 17 is connected to a high-voltage connection 20 (FIG. 5), which is used for Connection of an ignition cable, not shown, is used. The primary and secondary windings of the ignition armature 10 are Impregnated with insulating material and, together with the high-voltage connection 20, by a plastic jacket 21 surround.

The mode of operation of the ignition armature 10 during operation of the internal combustion engine is such that that of the rotating pole wheel Flux change generated in the iron core 11 in the primary and secondary windings induces a voltage which, when the Primary circuit drives a primary current through the primary winding. At the ignition point, the Primary current in the primary winding 14 through a not shown mechanical or electronic interrupter switched off suddenly. This very large change in current causes a strong change in the magnetic flux in the ignition armature 10, which is now also in the secondary winding 15 Due to the large number of turns, a high-voltage pulse of up to 30 kV occurs briefly, which is applied to the electrodes of the Spark plug, not shown, generates an ignition spark. When the ignition spark flashes over, the ignition voltage breaks abruptly together and the ignition energy is then discharged in a high-frequency oscillation, the Spark is maintained over several ms.

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In the very rapid collapse of savings when the ignition spark flashes over, the voltages occurring between the individual layers of the secondary winding.15 are essentially determined by the capacitances between these layers. In Fig. 2.i8t the equivalent circuit diagram for the voltage distribution on the secondary winding 15 is shown with a spark plug connected to it. The capacitances CL between the individual layers 18 of the secondary winding 15 are connected in series. The spark gap F of a spark plug lies parallel to this. The location. 18a with the beginning of the secondary winding 15 has the capacitance Cj. and the layer 18e with the end of the secondary winding 15 the capacitance Ctj ,. In known ignition armatures, the capacitance is CL. at the beginning and the capacitance CL-g at the end of the secondary winding less than the layer capacitance CL »because the windings there are blocked - that is, wound at a distance from one another - and have several intermediate insulations. The series connection of these capacitances does not result in a uniform voltage distribution when they are recharged during the ignition process. The voltage at the capacitances CL _A and CL- is significantly higher than at the capacitances CL in between, so that if such ignition armatures fail, a sparkover can be seen at the beginning or at the end of the secondary winding.

In the case of the ignition armature 10, such a sparkover is provided according to the invention thereby avoided that the capacities CL. and CL-, the starting position 18a and the end position 18e of the secondary winding 15 are at least as large as the capacities CL of the intermediate layers 18. The increase in the Capacities of the start and end positions of the secondary winding are achieved by the fact that at the beginning and at the end of the secondary winding 15 an isolated overlapped metal layer

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is inserted, which extends over at least part of the layer width of the secondary winding 15.

In Fig. 3, the first layers are over the primary winding 14 arranged secondary winding 15 is shown. The beginning of the relatively thin secondary winding wire 17 is wound several times around the end of the relatively thick primary winding wire 17 and with it electrically connected. A self-supporting metal foil 22a used as a metal layer is then applied together with the beginning of the secondary winding 15 and a paper film 23 in an overlapped position the primary winding 14 applied.

In Fig. 4 is an enlarged cross-section shown * like the overlapping areas of the Metal foil 22a to avoid a so-called short-circuit winding through the paper foil 23a from one another Are isolated. The metal foil 22a, together with the first turn, forms the starting layer 18a of the secondary winding 15. Since the metal foil 22a extends over the full layer width of the secondary winding 15, its Capacity Cr. at least as large as the further layers 18 of the secondary winding arranged above it

In FIG. 5, the last layers 18 with the end of the secondary winding 15 and the high-voltage connection 20 attached to it are shown schematically. Due to the predetermined number of turns of the secondary winding 15, the last layer 18e is only partially wound. To increase the end position capacity (Vg, a metal foil 22b extending over the full layer width is used together with a paper foil 2Jb which - in the same way as the metal foil 22a at the beginning of the secondary winding 15 - is insulated and overlapped is contacted with the high-voltage connection 20,

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which consists of a sheet metal strip 20a and a metal pin ^ς 20b with a wooden screw thread.

The invention is not limited to the exemplary embodiment shown limited, as other types of metal layers are used instead of a self-supporting metal foil can be. It is particularly advantageous if the metal layer is on one side of the paper foil 2 ^ a or 23b is applied, preferably vapor-deposited. Even Plastic films can be used to which the metal layer is applied on one side, provided a suitable impregnating agent is used. The measures described to increase the dielectric strength can be implemented with magneto ignition systems as well as with battery ignition systems. It is there too It does not matter whether the ignition coils or ignition transformers are open or closed Iron core acts. It is essential to the invention that the layer capacitance at the beginning and at the end of the secondary winding is at least approximately as large as the capacity of the intermediate layers.

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Claims (5)

'■ I ■ · ι 16 0 claims 1.j ignition coil, in particular ignition armature for magneto ignition of internal combustion engines with an iron core and an insulation body attached to it, which carries a primary and a secondary winding, whereby the beginning of the external secondary winding consisting of several winding layers is connected in series with the end of the primary winding, and the end of the secondary winding carries a high-voltage connection for an ignition cable, characterized in that the capacitance ((λ., ^ τ, Ε ^ ^ ^er ^ ⁿ ^ ^at S ^s ' ~ ^ur id end position (18a, 18e) of the secondary winding ( 15) is at least as large as the capacity (Ct) 'of the intermediate layers (18). 2. Ignition coil according to claim 1, characterized in that at the beginning and at the end of the secondary winding (15) a insulated overlapped metal layer (22a, 22b) is inserted, which extends over at least part of the layer width of the Secondary winding (15) is sufficient. - 10 - 509808/0473 - ίο - 3. Ignition coil according to claim 2, characterized in that that the metal layer (22a, 22b) extends over the full layer width of the secondary winding (15). 4. Ignition coil according to claim 2 and 3> characterized in that that the metal layer consists of a self-supporting metal foil (22a, 22b), which together with an insulating material olie (23a, 23b) is wound into an isolated overlapped layer. 5. Ignition coil according to claim 2 and 3, characterized in that that the metal layer is applied to one side of a paper foil. 6. Ignition coil according to claim 2 and 3> characterized in that that the metal layer is applied to one side of a plastic film. 5 09808/0473