DE4026532A1 - I.C engine distributor - Google Patents

Abstract

An i.c. engine distributor has a housing, fitted with a rotor arm having a first electrode near its rotational axis, a second electrode at its end remote from the rotational axis and a conductor connecting the two electrodes. The distributor cap has several fixed electrodes at its inner periphery for cooperating with the second electrode of the rotor arm and has a central electrode forming a spark gap with the first electrode of the rotor arm. One electrode, in the electrode pair formed by the first electrode of the rotor arm and the central electrode of the cap, is in the form of a rod. The novelty is that the other electrode (9) of the electrode pair (2,9) surrounds the rod-like electrode (2) either over less than half its circumference or not at all. Pref. one or both electrodes of the electrode pair (2,9) consist of or are tipped with a material which is nobler than Cu (pref. an Ag-contg. or Pd-contg. composite or alloy) or a material hVin SSivlin film (rf. U-Ni llOy Or r Sll).

Description

Technical field

The invention relates to an ignition distributor for internal combustion engines with a housing in which a distributor rotor is rotatably mounted, which has a first electrode close to its axis of rotation and a second electrode at its end remote from the axis of rotation and in between one connecting the two electrodes has electrical wiring,
and with a distributor cap which closes the housing and which has a plurality of fixed electrodes cooperating with the second electrode of the distributor rotor and a central electrode which ends on the inside on the circumference and ends with a spark gap at a short distance from the first electrode of the distributor rotor,
wherein in the pair of electrodes formed from the first electrode of the distributor rotor and the center electrode, an electrode is designed in the form of a pin.

State of the art

Such an ignition distributor is from DE-37 43 940 A1 knows. In the known distributor, the first is Electrode of the distributor rotor, which together with the Center electrode of the distributor cap bil a spark gap det, designed as a socket into which the pin-shaped Center electrode protrudes. Both electrodes are - as usual with spark gaps - made of brass. So that Flashover at the lowest possible arc span is achieved, the aim is to reduce the effective distance between keep the two electrodes as low as possible; he is typically 0.5 mm and should be a maximum of 1 mm.

The electrodes of the spark gap are subject differently than the usual sliding contacts between the Ver divider and the center electrode of the distributor cap no mechanical wear, yet life is duration of the electrodes forming the spark gap so far unsatisfactory.

Presentation of the invention

The present invention is based on the object an ignition distributor of the type mentioned with a longer one Lifetime of the center electrode of the distributor cap enclosing pair of electrodes.

This problem is solved by using an ignition distributor the features specified in claim 1. Beneficial Further developments of the invention are the subject of the Unteran claims.  

In the search for the solution according to the invention was festge represents a cause of wear in the middle Electrode pair is that the two electrodes are not are arranged exactly coaxially to each other. As a result, that the pin-shaped center electrode of the distributor cap over their girth burns unevenly because of the spark before moves at the narrowest point of the annular gap between the middle electrode and the socket-shaped electrode of the distributor rotor skips. The obvious way to solve the problem in Measures to look for deviations from an exactly coaxial However, reducing order did not lead to success, because on the one hand, it shows that due to structure and arrangement Ignition distributor the observed deviations from the exactly coaxial arrangement are practically unavoidable for others show that even with improved coaxial Arrangement of the two electrodes is still too strong an electric the wear occurred, which led to an inadequate service life The inventors then found that the electrode ver wear is not only due to spark erosion, but that the electrode surface is also attacked chemically. The chemical attack probably has different causes. To the it comes through the flashover and which accompany him de energy conversion to stimulate the surrounding gas atmosphere, whereby ozone and nitrogen oxides are likely to form. Also under  the electrodes and the surrounding plastic are one considerable thermal stress from the spark charges so that components of the plastic decompose and are released, including chlorine-containing components flame retardant substances. This is probably where the training comes from of an aggressive gas mixture which is applied to the top of the electrodes surfaces and contributes significantly to their wear.

The inventive design of the ignition distributor achieved two things: Because the electrode, which with the pin-shaped electrode works together, not as with State of the art is a socket, which is the pin-shaped Electrode around its entire circumference, but one Electrode, which the pin-shaped electrode is not or over encloses less than the entire scope, even at lack of coaxial arrangement of the sparks not always at the roll over the same place on the pin-shaped electrode, but must forcibly migrate, the burn-up all the more becomes more uniform the smaller the angle through which the pin-shaped electrode enclosed by the other electrode becomes. The pin-shaped electrode is therefore different from the other Electrode preferably less than half the circumference enclosed. In addition, the aggressive gases, the Er generation accompanies the spark discharge, from the area of the electrodes escape more easily if the pin-shaped elec unlike the prior art, no longer trode from one closed socket is surrounded. It is particularly cheap if those other electrode that together with the pin-shaped  Electrode forms the spark gap, one of the pin-shaped Has an essentially flat surface facing the electrode, because then you get a particularly smooth down fire of the pin-shaped electrode and the escape of the aggressive gases from the electrode area is special light and becomes when the pin-shaped electrode the The center electrode of the distributor cap is still thereby that the other favors dealing with the distributor runner rotating electrode that provides air movement that the The aggressive gases escape from the electrode area promotes, especially if the flat surface of the rotating electrode against the longitudinal axis of the pin shaped electrode is inclined or skewed.

In principle, the invention can be carried out in such a way that the pin-shaped electrode is either the central electrode of the Distributor cap or the first electrode of the distributor rotor , the first option being preferred because it is allows better ventilation of the electrode area light as if the pin-shaped electrode on the distributor would be appropriate. To improve ventilation it is advantageous to use the first electrode of the distributor rotor not to be installed recessed in the distributor rotor as before, but they protrude from the main body of the distributor rotor and in the space between the distributor rotor and the ver to let the divider cap protrude. It is preferable to let them in Room continues in an extension of the distributor rotor stick out like a fan blade for an additional  Air circulation ensures. The first electrode of the distributor part of this can be pre-run for air circulation seen extension or be separated from it for example - diametrically opposed to the axis of rotation overlap.

The pin-shaped electrode is separated from the other electrode partially surrounded, so it can vent the electrodes be conducive to the surrounding electrode by trained to train. Another way of ventilation to improve the electrode area consists in Distribution rotor in the area of the pin-shaped electrode through hole to provide, which is convenient against the pin-shaped center electrode of the distributor cap overlap, but not in the direction of the axis of rotation must, but preferably runs obliquely to the axis of rotation, whereby a pumping effect is achieved.

Another way to get the electrode area well ventilation, consists of the pin-shaped electrode and the other electrode not next to each other, but against each other to be arranged so that the sparkover from the Tip of the pin-shaped electrode to the opposite Electrode takes place, which is preferred to the pin-shaped electrode a flat surface that is larger than the cross-sectional area of the pin-shaped electrode, so that Deviations from an exactly coaxial arrangement for the Be driving the spark gap are harmless.  

Another way of ventilating the spark gap to improve is to get the first electrode the distributor rotor on its one of the pin-shaped means electrode facing the distributor cap with a Projection, in particular with a pin-shaped electrode parallel rib provides the effect of a ventila has wing. A further increased service life is achieved one, if you have this lead from a material with higher Wear resistance forms when the electrode in the loading has rich outside the projection; outside the Be area of the projection where the electrode has no spark exposed to charge, it can be easily processed ed, electrically good conductive material such as copper or Made of brass, on which the more wear-resistant projection is welded on. With a suitable choice of materials you can to wear-resistant electrodes in different ways reach. One way is to get the electrode out to manufacture a material or to be with a material pieces that are more noble than copper. Are particularly suitable Materials containing at least 20% by weight silver or at least Contain 10% by weight of palladium, especially silver-nickel Composites or palladium-copper alloys. Especially materials made of silver with 10 to 40% by weight are suitable, preferably 30 wt .-% nickel or palladium with 10 to 30% by weight, preferably 15% by weight of copper. Such work fabrics are admitted for use as electrical contacts known as materials for electrodes in spark gaps  however unusual. They show through their precious metal content increased chemical resistance to the aggressive Gases created by spark discharge.

Another advantageous way of being chemical resistant speed of the electrodes is to make them from the factory manufacture substances or to equip them with materials that cover with a passivating top layer. In this Materials from the group are particularly suitable the alloys of copper with nickel, the nickel content expediently between 10 and 40 wt .-%, preferably un is about 30% by weight; by adding little iron (1 to 2 wt .-%) can the chemical resistance even further be improved. Works are also suitable for the electrodes materials made from chromium alloyed steels because they a passivating layer of chromium oxide before the attack protect the aggressive gases. This too with a passi Materials covering the top layer are for electrical engineering not common in spark gaps.

It also has a positive effect on the electrode life, if you give the electrode material small amounts of a substance which lowers the electron work function, e.g. B. Thorium oxide. Electrodes with lower electron exit work requires a smaller arc for the arcing voltage and that means that the sparkover from one lower energy turnover is accompanied. As a result, in the ignition distributor not only reduces electrical losses, son less reactive gases are also generated.  

Way of carrying out the invention

An embodiment of the invention is shown schematically in the accompanying drawings.

Fig. 1 shows an ignition distributor in cross section; the section is perpendicular to the axis of rotation of the distributor rotor through the distributor rotor, according to section line AB in Fig. 2;

Fig. 2 shows the relative arrangement of distributor cap and distributor rotor in a longitudinal section through the axis of rotation of the distributor rotor according to section line EF in Fig. 1, and

Fig. 3 shows a further longitudinal section through the arrangement of distributor cap and distributor rotor, namely offset by 90 ° in comparison to FIG. 2, according to the section line CD in Fig. 1st

From the housing of the ignition distributor, only the distributor cap 1 is shown which several comprises a pin-shaped means electric de 2 and distributed at its periphery to the central electric de 2 parallel fixed electrodes 3, which have on the inner side of the distributor cap of the center electrode 2 facing electrode surfaces 3 a.

In the ignition distributor there is a distributor rotor 4 , which can be rotated about an axis 5 which extends coaxially to the center electrode 2 . The flat base body of the distributor rotor has three bores 6 , 7 and 8 for fastening the distributor rotor at the end of the camshaft of an internal combustion engine, the housing (engine block) of which also forms one half of the housing of the distributor, the other half of which is the distributor cap 1 . The distributor rotor carries two electrodes. A first, elongated electrode 9 is arranged on the upper side of the base body of the distributor rotor 4 , extends in the radial direction and ends tightly, namely at a distance of approximately 0.5 mm, in front of the outer surface of the cylindrical center electrode 2 of the distributor cap. At a radially outward location of the distributor rotor carries a second electrode 10 having a radially outwardly facing surface having a hard electrode 3 passes upon rotation of the distributor rotor at a small distance from the surfaces. 3 The electrodes 9 and 10 are connected to one another by an electrical line 11 embedded in the distributor rotor.

As best shown in Fig. 3, it is the first, with the center electrode 2 cooperating Elektro de 9 of the distributor rotor is a cuboid electrode, which has a flat end face 9 a of the center electrode 2 . The normals of the radially extending surfaces of the electrode 9 enclose an angle of approximately 45 ° with the axis of rotation 5 of the distributor rotor 4 .

Due to this orientation, the electrode 9 acts like a fan blade, which ensures air circulation in the space between the distributor rotor 4 and the distributor cap 1 . The air circulation is amplified by an electrode 9 diametrically opposite extension 12 of the distributor rotor. Due to the air circulation, a constant air exchange takes place in the area of the spark gap, which is formed between the center electrode 2 and the first electrode 9 of the distributor rotor, which removes the aggressive gases accompanying the flashover, thereby removing the electrodes 9 and 2 from their chemical attack. In addition, the center electrode 2 is not stressed on one side, but burns evenly because the first electrode 9 of the distributor rotor is arranged on one side next to the center electrode 2 and is guided around it.

Industrial applicability

The invention is in the field of the automotive industry (Her manufacturer, supplier, spare parts business) applicable.

Claims (25)

1. Distributor for internal combustion engines with a housing in which a distributor rotor is rotatably mounted, which has a first electrode near its axis of rotation and a second electrode at its end remote from the axis of rotation and an electrical line connecting the two electrodes therebetween.
and with a distributor cap which closes the housing and which has a plurality of fixed electrodes cooperating with the second electrode of the distributor rotor and a central electrode which ends on the inside on the circumference and ends with a spark gap at a short distance from the first electrode of the distributor rotor,
wherein in the pair of electrodes formed from the first electrode of the distributor rotor and the central electrode, an electrode is pin-shaped, characterized in that
that the other electrode ( 9 ) of the pair of electrodes ( 2 , 9 ) does not enclose the pin-shaped electrode ( 2 ) or less than the entire circumference. 2. Distributor according to claim 1, characterized in that the other electrode ( 9 ) of the pair of electrodes ( 2 , 9 ) encloses the pin-shaped electrode ( 2 ) over less than half the circumference. 3. Distributor according to claim 1, characterized in that the other electrode is opposite the tip of the pin-shaped electrode ( 2 ). 4. distributor according to claim 2 or 3, characterized in that that other electrode ( 9 ) one of the pin-shaped elec trode ( 2 ) facing, substantially flat surface ( 9 a). 5. Distributor according to claim 2 and 4, characterized in that the normal on the flat surface ( 9 a) against the longitudinal axis ( 5 ) of the pin-shaped electrode ( 2 ) is inclined. 6. Distributor according to one of the preceding claims, characterized in that the first electrode ( 9 ) of the distributor rotor ( 2 ) protrudes from the base body of the distributor rotor ( 4 ) and protrudes into the space between the distributor rotor ( 4 ) and the distributor cap ( 1 ) . 7. Distributor according to one of the preceding claims, characterized in that the distributor rotor ( 4 ) an eccentrically arranged with respect to its axis of rotation ( 5 ), from its base body into the space between the distributor rotor ( 4 ) and the distributor cap ( 1 ) projecting extension ( 12 ), which is electrically insulated from the first electrode ( 9 ). 8. Distributor according to one of the preceding claims, characterized in that the pin-shaped electrode ( 2 ) is the central electrode. 9. Distributor according to claim 8, characterized in that the distributor rotor ( 4 ) has a through-hole opposite the pin-shaped electrode ( 2 ). 10. Distributor according to one of the preceding claims, characterized, that the other electrode is perforated. 11. Distributor according to one of claims 3 to 7, there characterized by that the other electrode is also pin-shaped. 12. Distributor according to claim 11, characterized net, that the two pin-shaped electrodes in diameter are different. 13. Distributor according to claim 4, characterized in that that the other electrode on their the pin-shaped Electrode-facing side has a projection. 14. Distributor according to claim 2 and 13, characterized in that the projection is a rib which runs parallel to the pin-shaped electrode ( 2 ). 15. Distributor according to claim 13 and 14, characterized ge features that the projection from a material with a higher Ver Wear resistance exists as the electrode in the area has outside the projection.   16. Distributor according to one of the preceding claims, characterized in that at least one electrode of the pair of electrodes ( 2 , 9 ) consists of a material or is equipped with a material which is more noble than copper. 17. Distributor according to claim 16, characterized in that that the material from the group of composite materials or alloys with at least 20% by weight of silver or with at least 10% by weight of palladium is selected. 18. Distributor according to claim 17, characterized in that that the material made of silver with nickel or Pal ladium with copper. 19. Distributor according to claim 18, characterized in that the material made of silver with 10 to 40 wt .-%, preferably 30 wt .-% nickel, or of palladium with 10 to 30 wt .-%, preferably 15 wt .-% copper. 20. Distributor according to one of claims 1 to 15, characterized in that at least one electrode of the pair of electrodes ( 2 , 9 ) consists of a material or is equipped with a material which is coated with a passivating cover layer. 21. Distributor according to claim 20, characterized in that that the material from the group of alloys of Copper with nickel and the chrome alloyed steels chooses.   22. Distributor according to claim 21, characterized draws, that the material is an alloy of copper with 10 to 40 % By weight, preferably 30% by weight, of nickel. 23. Distributor according to claim 22, characterized in that that the material contains up to 2% by weight of iron. 24. Distributor according to claim 16 or 17, characterized ge indicates that in the material one for the che mixing inertia determining component and a ver wear resistance to spark erosion increasing com components are combined. 25. Distributor according to claim 16 or 20, characterized ge indicates that the material contains up to 5% by weight the substance that reduces the electron work function holds.