DE1180193B - Magnetic electric ignition generator - Google Patents

Description

Magneto-electric ignition current generator The invention relates to magneto-electric ones Ignition current generator with which only one ignition current surge is generated for each full revolution will.

The object of the invention is to provide an improved magneto-electric Ignition current generator of the above type, which can be made particularly small and also only delivers a spark at a certain rotational position.

According to the invention, this is achieved in that the ignition current generator two separate, with four magnetic pole pieces of unequal length and alternately opposite one another Has polarity cooperating anchor cores and the arc lengths between successive Armature pole centers roughly coincide with those viewed in the same circumferential direction Arc lengths of the inner surfaces of the magnetic pole pieces, so that only on a very specific one Point of the anchor circumference both cores are penetrated by a maximum flow, which immediately afterwards changes into a maximum flow of opposite polarity.

So as not to get from the ordinary insulation on the high-voltage wires to be dependent between the coils located on the two armature cores it is useful if, according to the invention, those located on the two anchor cores Coils and their connections are enclosed by a common insulating body are.

In the drawing, embodiments of the invention are given as examples shown.

F i g. Figure 1 shows a vertical cross section of one embodying the invention magneto-electric ignition generator, the cut along the broken Line 1-1 in FIG. 2 is taken; F i g. 2 shows a vertical longitudinal cross-section along line 2-2 in FIG. 1; F i g. 3 and 4 show side and front views a coil unit forming part of the stator; F i g. 5 shows a circuit diagram electrical connections; F i g. 6 to 19 show schematic views of the rotor in various positions; F i g. 20 shows in one of FIGS. 1 similar view a further modified embodiment of the invention; F i g. 21 and 22 are the F i g. 3 and 4 are similar views and show a coil and capacitor unit, which is part of the in F i g. 20 forms the rotor shown; F i g. 23 shows a Modification of the electrical circuit according to FIG. 5. To explain the invention, an embodiment of the ignition current generator is shown in which the induced Part is fixed and the part generating the magnetic field revolves and the induced Part surrounds. For the invention, it does not matter which of the two parts revolves.

As is known per se, the stator of the magneto-electric ignition generator is carried by a frame 10 which has a central opening through which the rotor shaft 12 extends. The stator has two magnetizable armature cores 14 and 16 with four pole faces 18, 20 and 22, 24, respectively. The cores are preferably layered from plates and their pole faces are curved concentrically to the axis of the shaft 12. The pole faces are the same distance from the axis and preferably have the same arc lengths in the circumferential direction. The cores 14 and 16 are firmly connected to the frame 10 by screws 26, 26 and 28, 28, respectively.

A primary coil 30 is arranged on the core 14 , the ends of which are at a distance from the pole faces of the core. A similar primary coil 32 surrounds the core 16. A secondary coil 34 surrounds the coil 30 and the core 14 and is preferably made slightly shorter than the coil 30. A similar secondary coil 36 surrounds the coil 32 and the core 16.

The primary coils 30 and 32 can be connected in parallel or in series. In the case of the in FIG. 5 they are connected in series through the connection 38. The secondary coils 34 and 36 are connected in series through the connection 40 . A wire end 42 of the primary coil 30 and a wire end 46 of the secondary coil 34 are grounded at 44 and 48, respectively. The wire end 50 of the primary coil 32 is connected to the movable contact 52 of the breaker, while the associated contact 54 of the breaker is grounded at 56. In a manner known per se, a capacitor 57 is connected in parallel to the interrupter contacts by means of the wires 58 and 59. The wire end 60 of the secondary coil 36 is connected to the spark plug 62.

As is known, the contact 52 of the breaker is arranged on a breaker lever 64 which is articulated at 66 on the frame 10. The interrupter lever 64 has an extension 68 which cooperates with a cam 70 fastened on the shaft 12. A spring 72 connected in an electrically conductive manner to the wire 50 by a screw 73 tends to pivot the lever 64 so that the contact 52 comes into contact with the contact 54. As the shaft 12 rotates, the cam 70 causes the breaker lever 64 to oscillate back and forth so that the electrical connection between the contacts 52 and 54 is periodically closed and interrupted.

By arranging two separate ones, each with a primary and a Secondary winding provided armature cores is achieved that the magneto-electric Ignition power generator can be made smaller than would otherwise be required. In order to achieve the required spark intensity, a certain total number must of coil windings are provided. When the necessary number of turns in a single primary and secondary coil are provided, the outer diameter the secondary coil is relatively large, so that the surrounding rotor accordingly must be carried out large in diameter and also in the axial direction. In the illustrated embodiment, each coil is only about half the size, and the two pairs of coils are set up so that the dimensions of the ignition current generator can be reduced significantly. Furthermore, there is a certain iron cross-sectional area required in the anchor cores. By providing two cores, the Wire length in each turn of each coil is reduced, as is the outside diameter each coil.

The armature cores 14 and 16 are sized and positioned such that the centers of their pole faces are unequal angularly spaced with respect to any plane passing through the axis of the shaft 12. In other words, the arc lengths between the centers of two respective pole faces of the armature poles 14 and 16 are unequal and all different from one another. The two cores 14 and 16 have different lengths and are angled to one another. As in Fig. 1, the angular distance between the centers of the pole faces 24 and 18 is the smallest with an included angle A, the distance between the centers of the pole faces 18 and 20 is greater with an included angle B, and the distance between the centers of the pole faces 22 and 24 is even larger with an included angle C, and the distance between the centers of the pole faces 20 and 22 is greatest with an included angle D.

The rotor of the magneto-electric ignition current generator has four magnetic pole pieces 82, 84, 86 and 88, which are magnetized by associated magnets with alternately opposite polarity. According to FIG. 1, a permanent magnet 90 is arranged between the pole pieces 82 and 84 and a permanent magnet 92 is arranged between the pole pieces 86 and 88. The inner surfaces of the magnetic pole pieces are arcuate concentric to the axis of the shaft 12 and are at a short distance from the arcuate pole faces 18, 20, 22 and 24 of the armature cores 14 and 16. The two magnets 90 and 92 are arranged so that the pole pieces 82, 84, 86 and 88 alternately have opposite polarity.

The magnets 90 and 92 are like this in sections of the magnetic pole pieces arranged that their inner surfaces at a distance from the inner surfaces of the pole pieces lie. Between the adjacent end faces of the pole pieces are essentially equally large column provided.

The magnetic pole pieces and magnets are carried by a housing 94 made of non-magnetic metal which is mounted on the shaft 12 . As shown, the housing 94 can be an injection molded piece molded around the pole pieces and magnets. The housing is provided with a hub 96 which receives the shaft 12.

The magnetic pole pieces 82, 84, 86 and 88 have unequal arc lengths, and the arrangement is such that the arc lengths between successive pole centers of the armature cores 14 and 16 approximately correspond to the arc lengths of the inner surfaces of the magnetic pole shoes viewed in the same circumferential direction. This can easily be seen when the rotor is in the position shown in FIGS. 1 and 19 is the rotational position shown. Like F i g. 1 shows, the lengths of the magnetic pole pieces are dimensioned so that the different pole pieces plus half of the two immediately adjacent gaps enclose the respective arc angles A, B, C and D.

When the circuit of the primary windings (coils 30 and 32) is closed, a current is induced in the primary windings when the rotor rotates, which current is proportional to the changes in the total flux in the two armature cores 14 and 16 . The total changes in flow at various successive positions are shown in FIGS. 6 to 19 schematically illustrated, it being assumed that the rotation of the rotor is clockwise.

With respect to FIG. 6 to 19, the direction of flow in the anchor cores 14 and 16 is designated as "clockwise" and "counterclockwise" for the sake of simplicity.

The F i g. 6 shows the rotor in a rotational position somewhat beyond that in FIG. 1 position shown. The position of the F i g. 6 is that which immediately follows the spark generation at the spark plug 62. The core 14 has south polarity on the right and north polarity on the left, the flow in it runs clockwise. The core 16 has north polarity at the lower end and south polarity at the upper end, the flux in it runs clockwise. The total flow is clockwise and has a maximum value.

In the position of FIG. 7, the core 14 has south poles at each end and little or no flux. The core 16 still has north polarity at the lower end and south polarity at the upper end, the flux in it remains clockwise. The total flow is clockwise and is approximately half the maximum value.

In the position of FIG. 8 the core 14 has north polarity on the right and south polarity on the left, the flow in it runs counterclockwise. The core 16 has north polarity at the lower end and south polarity at the upper end, the flux in it is clockwise. Since the directions of flow are opposite, the differential flow is approximately zero.

In a corresponding manner from FIGS. 9 to 17 can be seen that upon further rotation of the rotor into the positions shown in these figures the total flow is either about zero or about half of the maximum value having, wherein it runs clockwise or counterclockwise.

In the position of FIG. 18 the core 14 has north polarity right and South polarity left, so that the river is counterclockwise. The core 16 has south polarity at the lower end and north polarity at the upper end, the river runs in it counter clockwise. The total flow again reaches the maximum value, however in the to the in F i g. 6 direction opposite direction.

It follows accordingly that during the rotation of the rotor of the in FIG. 6 by the position shown in F i g. 7 through 18, changes in the total flow from a maximum value in one direction as shown in FIG. 6 is shown to one in F i g. 18 result in the opposite direction. Each individual change is only half of the maximum flow in one direction or the other, and the total flow in the areas shown in FIG. 7 to 17 is either zero or approximately half of the maximum flow. This is illustrated in detail in the table below, in which the clockwise flow is designated as positive and the maximum flow in each core is designated by the number "1". Fig. Flow in core 14 Flow in core 16 Total flow 6 clockwise clockwise + 2 7 0 clockwise -f- 1 8 counter clockwise clockwise 0 9 counterclockwise 0 - 1 10 0 0 0 11 0 counterclockwise - 1 12 clockwise counterclockwise 0 13 clockwise 0 + 1 14 0 0 0 15 0 clockwise + 1 16 0 0 0 17 counterclockwise 0 - 1 18 counterclockwise counterclockwise - 2 While the total flow peaks counterclockwise as shown in FIG. 18, the rotor rotates to the position of FIG. 19, which between the positions of FIG. 18 and 6 lies. During this movement, the cam 70 causes the breaker contact 52 to move so that the circuit through the primary coils 30 and 32 is closed. While the rotor by the position of the F i g. 19 goes, the flow direction becomes counterclockwise from the maximum value as shown in FIG. 18, suddenly reversed clockwise to the maximum value, as in FIG. 6, and the breaker contact 52 is moved by the cam to break the circuit. The sudden change in the flux from the maximum value in one direction to the maximum value in the opposite direction results in a maximum change in flux at the moment the circuit is interrupted by the primary coils. This maximum change in flux induces a high voltage current in the cascaded secondary windings, and this high voltage current creates a spark at the plug 62. After the circuit is broken, the rotor rotates to the position shown in FIG. 6, and the working cycle described is repeated in the same way.

When comparing the table above and the description above, it can be seen that in the ignition current generator designed according to the invention, the spark during the maximum change in flux from "-2" to "-f-2" in the position of FIG. 19 is generated, with a change in total flow of "4" occurring. In no other position during the work cycle does the change in flow exceed "1", ie a quarter of the maximum change. The possibility of generating an uncontrolled spark in any intermediate position of the working cycle is therefore excluded with the greatest possible certainty.

In order to achieve perfect insulation of the connections 38 and 40 between the coils of the two pairs, in particular of the high-voltage wire 40 connecting the two secondary coils, a single, uniform body 74 made of insulation material around the coils 30, 32, 34 is expedient in a manner known per se and 36 and formed around connecting wires 38 and 40 (Figs. 3 and 4). The cores 14 and 16 can be inserted into the coils before or after the insulator 74 is formed.

The insulating body 74 expediently has two relatively large main parts 76 and 77 which surround the coils 30 and 34 and the coils 32 and 36, respectively. The ends of the angled cores 14 and 16 protrude from these main parts. The body 74 also has a smaller part 78 made of the same piece which connects the two main parts and encloses the wires 38 and 40. Preferably, the shaped body 74 has a rearward projection 79 which surrounds the lead wire 60 of the spark plug 62 .

Appropriately, as shown in FIGS. 20 to 22, the capacitor 57 required in such magnetic power generators can be surrounded and enclosed by the same shaped insulating body 98 that also surrounds and encloses the coils. Preferably, the capacitor is disposed in a connector 100 which is similar to connector 78 (Fig. 4). The body 98 is molded around portions of the wires 58 and 59 connected to the capacitor 57. One of the wires, for example wire 58, is connected to movable breaker contact 52. The other wire 59 is grounded by one of the screws 26 that hold the core 14. The capacitor 57 is consequently connected in parallel to the contacts of the interrupter, as in FIG. 5 shown.

The arrangement of the capacitor within the molded insulator saves additional space, especially since it is no longer necessary, a special one Provide fastening device for the capacitor.

F i g. 22 shows a further modification of the one shown in FIG. 5 shown circuit. The primary coils 30 and 32 are connected in series through the wire 38 and the secondary coils 34 and 36 through the wire 40. The secondary coils are connected to the spark plug 62 by the high voltage wire 60 in the same manner as in FIG. 5 connected. The opposite ends of the primary coils are grounded by wires 42 and 110 , and the breaker contact 52 is connected by a wire 111 to the connecting wire 38 of the two primary coils. The operation is essentially the same as that previously described.

Claims (2)

Claims: 1. Magnetic electric ignition generator, in which only one ignition current surge is generated for each full revolution, - It is not indicated that the ignition current generator has two separate, four magnetic pole pieces unequal length and alternately opposite polarity cooperating armature cores and the arc lengths between successive armature pole centers approximately coincide with the arc lengths considered in the same circumferential direction of the inner surfaces of the magnetic pole pieces, so that only at a very specific point of the anchor circumference, both cores are penetrated by a maximum flow that is immediately then turns into a maximum flow of opposite polarity. 2. Magnetic electric ignition generator according to claim 1, characterized in that the coils located on the two armature cores, together with their connections, are enclosed by a common insulating body. Considered publications: German Patent Nos. 906 869, 851 861, 808 997, 736 773, 581 744; USA: Patent No. 2,392,500.