DE567871C - Ignition device for explosion engines - Google Patents

Description

In the majority of magnetos for internal combustion or explosion engines every change in the magnetic flux is used to generate an ignition spark. In this case the flux of the lines of force changes direction with each spark.

To increase the strength of the spark and the heat it generates, one already has proposed to multiply the number of changes in the flux of force lines and only one Use part of these changes to generate the spark. With the so far known devices of this type, the primary current is running at the moment of interruption always in the same direction, causing metal migration on the breaker contacts also always takes place in the same direction. But this makes these contacts very much quickly destroyed.

It is the aim of the invention to obtain a hot ignition spark while avoiding the permanent rectified migration of metal. For this purpose, according to the invention, the cams of the interrupter are arranged in such a number that a single interruption takes place after each generation of a number of changes in force flow which is odd and greater than one.
In the drawings show:

Fig. Ι a view of the magnetic circuit a magnetic inductor according to the invention,

Fig. 2 is a diagram of the magnetic circuit shown in Fig. 1,

Fig. 3 shows a different embodiment in a schematic view similar to Fig. 2, and

Figs. 4 and 5 show a further embodiment in views similar to Figs.

In the embodiment shown in Figs the inductor has a magnet that has a shaft 1 made of a special Has steel, which on a middle, consisting of non-magnetic metal Shaft 2 is seated; this runs in not shown, supported by the inductor frame Bearings and is connected to the motor shaft by common organs. At the ends of the Shank 1 sit or are blown pole pieces 3, 4, which are made, for example, of layered, consist of sheets held together by means of shields.

Each pole shoe ring 3, 4 receives a certain number of legs 5, 6, depending on the number which depends on the spark to be obtained during one revolution of the inductor shaft. When executing According to Fig. 1, each pole piece has two asymmetrical with respect to the axis of rotation 2 Legs, and the two pole shoe carriers 3, 4 are in this way on the shaft 1 offset that each shoe 5 of one of the carriers, 3, the pole pieces 6 of the other carrier 4 diametrically opposite. The arrangement of the pole pieces is such that the two pole

shoes 5 and 6 of the carrier 3, 4 with respect to the angular positions follow one another (Fig. 1).

The inductor armature has a primary winding 7 which is connected to a conventional tear-off device and is centered on a core 8 made of magnetic metal, suitably peeled. The core sits firmly on two magnetic parts or bridges 9, io parallel to the shaft 1, each of which has pole pieces 11, 11 and 12, 12 at the ends, which are arranged opposite the armature pole pieces 5, 5 and 6, 6. The pole shoes 11 of the bridge 9 are offset with respect to those 12 of the other bridge 10 by an angle which is equal to the smallest angle separating the pole shoes 5, 6 of the two poles 3, 4 of the inducing part. As soon as one of the shoes 5 of the pole 3 is opposite the corresponding pole shoe 11 of the bridge 9, there is a shoe 6 of the other pole 4 opposite the pole shoe 12 of the other bridge 10. Assuming that 3 is a north pole and 4 is If the south pole is, the core 8 is traversed by the line of force current in the sense indicated by the arrow f , so that the current induced in the winding 7 has a specific direction.

If the shaft 1 is now rotated until the two other shoes of the poles 3, 4 again come across the pole shoes of the bridges 9, 10, ie by 180 ° (Fig. 1), the shoe 6 of the pole 4 comes across the pole shoe 11 the bridge 9 and the shoe 5 of the other pole 3 opposite the pole shoe 12 of the other bridge 10. The line of force current now flows against the arrow f in the core 8, and the direction of the primary current in the winding 7 is reversed. With each revolution of the inducing part 1, there are therefore two changes in the force line current, each of which corresponds to a change in direction of the current induced in the primary circuit 7. If the current through the tear-off current is interrupted with these two changes, two sparks are produced with each revolution of the inducing part, the direction of the current being reversed with each break-off. The magnetic inductor can therefore provide the ignition in a four-stroke and four-cylinder engine, the inductor shaft rotating at the speed of the motor shaft.

You can of course change the inductor poles 3, 4 in such a way that with each revolution of the inducing part results in a certain number of sparks. So is schematic in Fig. 3 a cross-sectional magnetic circuit of the inductor is shown, the four sparks delivers with every revolution. In this embodiment, each pole 3, 4 has four Shoes 5 and 6, which are grouped in pairs next to each other, with each group, that is, from consists of two shoes 5 of pole 3, angled between two groups of two shoes 6 each of the other pole 4 is arranged, the two angularly adjacent and different Poland associated shoes 5, 6 separating angles 6g the angular spacing of the pole pieces 11, 12 of the armature is the same.

As a result of the moving apart of the groups of the used one after the other with each flux change Pole shoes 5 and 6 do not take place this flux changes too quickly, so that the strength the chopping current is low. To increase this amperage and a hot spark the number of flux changes is increased by adding poles 3, 4 with a larger number of shoes 5, 6 (Fig. 4, 5) chooses. But there is the consequence of this If the number of flux changes is greater, the number of these pole pieces must be selected in such a way be that a corresponding tear-off only allows those flux changes to be used, those of the previous change used are opposite, with the number of at each Rotation of the field magnet is the desired spark to be obtained. 8g

Thus, the magnetic circuit shown in Figures 4 and 5 contains one for each revolution of the field magnet two sparks producing magnetic inductor-inducing poles 3, 4, each of which has three shoes 5 and 6, respectively. These Pole shoes are regularly offset by 120 ° with respect to one another, with the pole shoes of one pole are offset by 60 ° with respect to the pole shoes of the other pole, which The angle is that in which the two armature pole shoes 11, 12 are offset.

As soon as there is a pole piece 5 opposite a pole piece 11 of the bridge 9, comes a pole piece 6 of the other pole 4 opposite a pole piece 12 of the other bridge 10.

If the field magnet 1 rotates, the flux changes direction in the core 8 every time a pole of different polarity arrives in front of one of the pole pieces of the same bridge. It So every time the field is rotated, there are six 10g Flux changes, each of which is a change in the direction of the current induced in the primary current is equivalent to. If only one of three flux changes is used with the mediation of a corresponding tear-off device, then one obtains two breakaway sparks with each field rotation, and the primary current is reduced with each breakaway ; reversed.

With such a device, one secures at a corresponding speed 11g of the field magnet, the desired number of sparks with each revolution of the drive shaft as well as the inversion of the primary current each time it breaks. It stands to reason that the number of pole pieces of poles 3, 4 can be changed depending on the number of sparks to be obtained with each field revolution is what number of sparks from the

ratio of the speed of the motor shaft to that of the magnetic inductor and the number the cylinder in the engine depends.

The total number of pole shoes of the two poles 3, 4 must be a multiple of the number of sparks be, namely an odd multiple, so with each revolution of the field magnet and the primary current is reversed each time this occurs. The number of pole pieces Each pole must therefore be an odd multiple of half the number of sparks for each Be rotation.

In the embodiment according to Fig. 3, 4 a multiple equal to three has been chosen; the number of sparks is equal to two for one revolution. The number of pole pieces on each pole

is therefore equal to: 3 ■ ~ - = 3. If the multiple is equal to 3 and if you want four sparks with each revolution of the field magnet, then choose

man .3 · - = 6 shoes at each pole.

Claims (1)

Claim: Ignition device for explosion engines, in which the number of changes in the power flow in the magnet is greater than the number of interrupters in the primary circuit interruptions generated at regular intervals, characterized in that, that the cams of the interrupter are of such a number that a single interruption after each generation of a number of force flux changes that are odd and greater than 1 takes place. For this purpose ι sheet of drawings BERLIN. COVERED IN THE