JPS58172949A - Magnet generator for ignitor of internal combustion engine - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The invention relates to a magnet generator for an ignition system of an internal combustion engine, of the type defined in the preamble of the patent claims. In known magnetic generators, the different structural parts of the generator, which are attached to the armature plate, are received in a ring-shaped insulating disk fixed to the outer periphery of the armature plate. Patent Application Publication No. 2814782), the armature plate has a large number of armature cores with armature windings, and the armature winding body has contacts of the armature windings. are doing. The conductors for the armature windings are brought into contact with the contacts 1.5 and guided in grooves provided in the insulating disc into an opening common to all the conductors. However, a disadvantage of this known device is that it requires an armature plate for fixing the insulating disk and for fixing each armature. This armature plate must be fixed to the casing of the internal combustion engine. Further, by arranging the ring-shaped insulating disk around the outer periphery of the armature plate, the outer diameter of the magnet generator becomes undesirably large. Moreover, it is necessary to additionally provide a part of the collar for fixing the armature plate and the annular insulating disc, and if this part of the collar is provided, it is difficult to attach the armature plate to the casing of the internal combustion engine. becomes difficult. In order to protect the conductors installed on the insulating disc from external damage, a protective hood is additionally required, which is placed over the magnetic generator and attached to the outer edge of the insulating disc. There is a need. Moreover, by arranging the insulating disc around the outer periphery of the armature plate, relatively long conductor wires are required.

For this reason, such a construction is quite expensive to manufacture and requires special steps for this purpose, especially when installing a magnet generator of this type in an internal combustion engine that is configured in a connected manner. Requires a base. The object of the invention is to design a magnet generator for the ignition system of an internal combustion engine as tightly as possible, so that the conductors for connecting the armature windings are no longer required for this purpose. It is an object of the present invention to provide a magnet generator which can be constructed in such a way that it does not cause the above problems, and which can be manufactured simply and at low cost with the same efficiency.

The magnet generator according to the present invention having the features set forth in claim 1 allows the armature winding to be directly fixed to the casing armature core of an internal combustion engine, and the armature winding to the armature winding to the armature winding. The advantage is that the annular insulating disc with the connecting conductor can be attached in a simple manner on one side of the armature winding to the armature without any unrotatable jerking. Another advantage is that by arranging the annular insulating disk directly in the area of the armature winding, it is possible to keep the length of the connecting conductor as short as possible. Moreover, the solution according to the invention makes it possible to construct the magnetic generator in a compact manner, so that additional protective hoods can be dispensed with.

Advantageous embodiments and improvements of the device according to the invention are possible with the measures specified in the dependent claims.

It is particularly advantageous if the insulating disk is provided with a number of detent projections divided around its periphery, which detent projections are engaged in corresponding recesses provided in the winding body of the armature winding. 6, which resulted in a quick, reliable and easy installation process.

Next, the configuration of the present invention will be specifically explained with reference to the embodiments shown in the drawings.

In FIG. 1, a magnet generator for the ignition system of an internal combustion engine is designated by the reference numeral 10. magnet generator 10
has a forest-shaped rotating flywheel 11 driven by an internal combustion engine (not shown), and this flywheel 1
A magnet 12 having a large number of magnetic poles of alternately different polarities is arranged on the inner periphery of the magnet 1 . The flywheel has armature 1
3, the star-shaped armature laminated core 1 of this armature 13
4 is fixed firmly and directly to the casing of the internal combustion engine (- with screws).The armature laminated core 14 has armature windings arranged in a star pattern at its legs for supplying the ignition system as well as other consumers. The winding body 17 has a contact 18, which connects each of the armature windings 16 to the main body 17. The ends of the armature windings 16 are respectively soldered or welded. Parts of the armature windings 16 are connected in series. One end of each armature winding is brought into contact with the armature laminated core 14. The conductor 19 is received in an annular insulating disc 20, and the other end is led to the outside via a conductor 19. The conductors 19 are guided as far as the contacts 1B on the winding body 17.The ends of the conductors 19 are each soldered directly to the contacts 18 of the armature winding 16 in the area of the insulating disk 20.

FIG. 2 shows a partially cutaway front view of the star-shaped armature 13 of the magnetic generator 10, with the cutaway portion showing the insulating disc 20. In FIG. The insulating disk 20 is arranged on the back side of the armature winding 16 and is fixed to the armature 13 by a locking member. In FIG. 1, the state before the insulating disk 20 is attached to the armature 13 is shown.

The insulating disk 20 is provided with a large number of locking protrusions 21 that are divided and arranged on the inner circumference, and the locking protrusions 21 are
0 in the direction of the arrow direction 13, the armature winding 1
6 in a corresponding recess 22 formed in the winding body 17. The insulating disk 20 is designed on its side facing the armature winding 16 as a groove 23 in which the conductor 19 is received when the insulating disk 2025 is inserted into the armature winding 16 . The conductive wires 19 are bundled and guided to the outside through an opening 24 provided in the groove bottom 23a.

The soldering point 25 as a connection point between the end of the conductor 19 and the contact 18 of the armature winding 16 is located inside the groove 23, which protects the contact point and keeps the conductor 19 as short as possible. be done.

Another embodiment of the invention is shown in FIGS. 3 and 4. In this embodiment, a plurality of conductor tracks 31 are embedded in an annular insulating disk 30, which conductor tracks 31 are produced by punching out a sheet of copper in the form of a punching grid 32. After embedding the conductor track 31 in the insulating disc 30, the inner ring 32a of the punched green P32 is cut off from the conductor track 31, so that the exposed end section 31a of the conductor track 31 is inserted into the insulating disc 30. Bent up from the surface. Furthermore, the conductor track 31 is separated at the connecting web 33, since both ends of the connecting web 33 are punched out. The end sections 31b of the conductor tracks 31, which lead to conductors (not shown), are each fastened to a plug-in pin 34 as a plug-in part and are releasably connected to the conductor by means of a connecting plug.

FIG. 4 shows a partially broken sectional view of the star-shaped armature 13a, showing an insulating disk 30 fixed to one side of the armature winding 16a by a locking projection 21a. . In the second half of FIG. 4, it can be seen that the bent end section 31a of the conductor track 31 is in contact with the end of the connection mark 18a of the armature winding 16a. The end section 31a of this conductor track 31 and the end of the connecting projection 18a are welded together. In this manner, the conductor track 31 is brought into contact on the one hand with the conductor and on the other hand with the contact 18a of the armature winding 16a.

The invention is not limited only to the illustrated embodiment.

That is, depending on the shape of the magnet generator, the contacts of the armature winding can be arranged in different positions, . The annular design of the insulating disk makes it possible to optimally guide the conductor without additionally fixing the conductor. In the embodiment of FIGS. 1 and 2, by providing the opening 24 in the groove bottom 23a, the conducting wire 19 can be bent at right angles in the area of the opening 24, so that the tensile load on the conducting wire can be relieved.

In the embodiments of FIGS. 3 and 4, another type of punched grid is used for the conductor track 31, or the conductor track 31 is embedded in the insulating disc 30 in the inner ring 32a and then the conductor Other contact points in the armature 13a are possible, depending on whether the universally usable punching grino P is punched out in such a way that only the end section 31a of the required length of the path protrudes from the insulating disk 30. According to FIG. 4, the end section 31a of the conductor track 31 is bent outward, so that the end section 31a connects the insulating disk 30 to the armature 13.
a, and then easily soldered or welded to the connecting protrusion 18a. The outwardly guided end section 3ib of the conductor track can be soldered directly to the ends of the conductor without a plug-in pin, or alternatively, instead of a plug-in pin, another soldered, welded or plug-in connection can be provided. good.

[Brief explanation of drawings]

FIG. 1 is a sectional view of an embodiment of a magnetic generator for an ignition device according to the present invention, showing the state before the insulating disk for receiving the conductor is fixed to the armature; FIG. 1st
A partially broken front view of the armature of the magnet generator shown in the figure.
FIG. 3 is a front view of another embodiment of the insulating disk, and FIG.
There is a sectional view showing a state in which the insulating disk according to the figure is arranged on the armature of a magnetic generator. 10... Internal combustion engine, 11... Flywheel, 12... Magnet), 13.13a... Armature, 14... Armature laminated core, 15... Leg, 1'6.16a. ... Armature winding, 17.17a ... Winding body, 18゜1
8a...Contact, 19...Conducting wire, 2o...Insulation-disk, 21.21a...Locking protrusion, 22...Notch,
23...Groove, 23a...Groove bottom, 24...Opening,
25... Soldering points, 30... Insulating disk, 31
... Conductor path, 31a, 31b... Termination section, 32.
...Punching Grino)', 32a...Ring, 33...
・Joining web, 34... Insert pin door continuation from page 1 0 Inventor Karl Wütt Schafhof Goethestrasse, Federal Republic of Germany 4

Claims (1)

[Claims] 1. A magnetic generator for an ignition system of an internal combustion engine, comprising a rotating flywheel around which a number of magnetic poles having alternately different polarities are arranged, and a plurality of fixed armature windings. and an annular insulating disc, the armature windings being arranged on the legs of the armature laminated core so as to cooperate with the base of the flywheel, of the type in which the conductor connections leading to the contacts of the armature winding are received in the insulating disc, the insulating disc (
20, 30) are arranged on the -blade side of the armature winding (16, 16a) and are connected to the generator by a locking member. 2, +eJi yen & (20, 30) lz1 round n*
l1gnfc is equipped with a large number of locking projections (21, 21a), and the locking projections (21, 21a) are connected to the armature winding (1
6, 16a) adapted to be locked in corresponding notches (22, 22 &) provided in the winding body (17, 17a). . 3. The side of the insulating disk (20) facing the armature winding (16) is formed as a groove (23), and the groove (23)
The conductor (19) of the armature winding (16) is received therein, and the conductor (19) is guided to the outside through an opening (24) provided in the groove bottom (23a). Magnetic generator according to scope 2. 4. Magnetic power generation according to claim 3, wherein the connection point (25) at the end of the conductor (19) contacts the contact (18) within the groove (23) of the insulating disc (20). Machine. 5 A conductor track (31) is embedded in the insulating disc (30), which is brought into contact with the conductor on the one hand and the contact point (of the armature winding (16a)) on the other hand. 1
8a). Magnetic generator according to claim 1, in contact with 8a). 6 The conductor path (
The terminal section (31a) of 31) is the armature winding (16a)
The connection protrusion (1) provided in the winding body (17a) of
8a). Magnetic generator according to claim 5, in contact with 8a). 7 Bent end section (31a) of conductor path (31)
7. Magnetic generator according to claim 6, in which each of the connecting projections (18a) is in contact with an end of the connecting projection (18a) and is welded to this connecting projection (18a). 8 The terminal section (31) of the conductor path (31) led by the conductor
b) is firmly attached to the insertion part (34) 1,'. A magnet generator according to claim 5, which is continued. 9 The conductor track (31) consists of a punched-out grid (32) and in the embedded state connects the connecting web (33).
The magnet generator according to claim 5, which is separated from the other at the point.