DE1439991C3 - Battery ignition system - Google Patents

Description

30th

The invention relates to a battery ignition system with an ignition coil and with a ii.i primary circuit of the Ignition coil lying transistor, which is arranged by an interrupter in its base-collector circuit is controlled from the conductive to the non-conductive state, and with one the emitter-base path of the transistor bypassing the parallel circuit, the one magnetically against the ignition coil contains decoupled inductance.

An ignition system of this type has become known from US Pat. No. 3,046,447, in which an inductance is provided in a circuit parallel to the emitter-base path of the switching transistor which is magnetically decoupled from the ignition coil and when the breaker is closed from a magnetizing current flows through it. When the breaker opens, an inductive Reverse voltage is generated, which makes the base of the switching transistor positive with respect to the emitter and this has the effect that the current flowing since then through the primary winding of the ignition coil is rapidly interrupted. Because of the unavoidable winding capacitances, however, follows in that which forms the inductance Auxiliary coil in direct connection to the positive voltage surge a negative voltage lock, by which the transistor is made conductive again. Contrary to the claims of the aforementioned Patent specification has since been able to use a auxiliary inductance alone no acceleration of the shutdown process can be achieved. Rather, the shutdown process was rather delayed or delayed, especially when in battery ignition systems The usual way, a breaker capacitor is arranged in parallel to the breaker contacts.

The invention is based on the object, in a battery ignition system, of the type described at the outset Type that contains an auxiliary inductance, the shutdown type input to accelerate. To solve this up »down it is proposed according to the invention that the Auxiliary inductance is connected in series with a rectifier. where the rectifier together; i with the emitter-base path of the transistor is the same Forward direction hai and with the breaker closed “Is tmmconductive. Through the Glcichrichkr is achieved that with a pnp transistor only the the first to start in the opening point of the breaker positive "Sp.iiiiiungsspitze to the base de-; The transistor can irkuriü unüehinderi, whereas the following, Negative voltage peak that occurs during oscillation is kept away from the transistor The measures according to the invention sohl 'prevent that "the transistor is open in spite of the fact that it is open Breaker becomes conductive again and then the Alv-chaltvoraana in the known Zündanbeen occurring, delayed manner described above.

It has proven to be particularly favorable if a capacitor is installed in parallel with the auxiliary inductance is provided. It is also advisable to have one in series / u of the auxiliary inductance and the rectifier Limitation; · Resistance to be arranged.

The proposed switching measures reduce the time it takes for the transistor to transition from his voil conductive to his locked Condition required, considerably shortened. This is particularly beneficial in the case of a rapid firing order Reduction of the power loss of the transistor when switching with it. As a result of the increase in permissible emitter-collector reverse voltage, it is possible to use cheaper transistor types in an ignition system to produce, which has a long service life.

The invention is described below using an exemplary embodiment shown in the drawing described and explained in more detail. He shows

1 shows a transistor ignition system in an overview and

Fig. 2 shows the electrical circuit diagram of the ignition system according to F ig. 1.

The transistor ignition system is used to operate a four-cylinder internal combustion engine (not shown) determined and is fed from a collector battery 10. It contains an ignition coil 11 with an in Fig. 2 to 12 indicated primary winding and a secondary high-voltage winding 13, the both are connected to a common connecting bolt 14, which is in the plastic cover 15 of the The ignition coil is seated and connected to ground via a line 16. The other end of the high voltage winding 13 is connected to the encircling electrode 18 of a distributor 20 via a cable 17. This contains a four-humped cam 21 and an interrupter lever cooperating with this 22. In the distributor housing there is also a drive shaft 23 for the breaker cam 21 stored. The distributor cover 24, which is made of insulating material, contains four fixed electrodes 25, each of which is connected via an ignition cable 26 to one of the four spark plugs, of which FIG. 1 shows only one indicated at 27.

In order to keep the current flowing through the primary winding 12 of the ignition coil in time with the opening and closing cycles Switching the closing operations of the interrupter lever 22 on and off is one indicated at 30 in FIG Apparatus is provided which includes a transistor 31

contains, the with its emitter to the positive pole of the Battery 10 leading positive lead 32 and its collector to the primary winding 12 of the ignition coil 11 is connected. The base /? this transistor is via a line 33 and a resistor 34 to the stationary with the interrupter lever 22 cooperating breaker contact 35 connected and arrives when the breaker lever is closed connected to ground. Then the transistor 31 can via the primary winding 12 a lead considerable current, which generates a strong magnetic field in the iron core 36 of the ignition coil. Sohald the interrupter lever 22 is raised by the interrupter cam 21 and thereby the stationary Contact 35 leaves if the transistor is off - ,, jm conductive in the non-conductive state UiKr, with high voltage winding in the secondary 13, an ignition voltage surge is generated and passed to one of the spark plugs 27 via the distributor electrode 18 will.

In order to considerably shorten the time that the transistor 31 needs for the transition from the current-conducting to the non-conducting operating state and to reduce the power loss occurring in the transistor during this switching process, an iron core 38 is installed parallel to the emitter-base path of the transistor 31 provided inductance 39 is provided. A semiconductor rectifier 40 which is permeable in the same direction as the emitter-base section of the transistor is arranged in series with this. The winding of the inductive circuit 39 is connected in series with a series resistor 41 directly connected to the positive line 32 and is connected in parallel with a capacitor 42. As long as the interrupter lever 22 touches its mating contact * 35, these two contacts can not only be used! Base current of the transistor 31 flow, but also, Mn to the emitter-base path parallel secondary current J which generates a magnetic field in the iron * τη 38 of the inductance 39. As soon as the interrupter lever 22 is lifted off, it interrupts the base current of the transistor 3t and the secondary current J _n . The magnetic field present in the iron core 38 generates an inductive voltage on the winding 39 at the instant of interruption. By making the potential of the base B of the transistor 31 briefly positive with respect to the emitter. In this way, a reverse current pits which is opposite to the direction of the base current and moves ^; rkt that the transistor quickly goes into its blocking state. The particular advantage that the use of the inductance 39 brings with it is that the transistor 31 is able to withstand considerably higher reverse voltages occurring between the emitter and collector due to the brief positive voltage spike at the moment of switch-off.

Here-to 1 sheet of drawings

Claims (3)

Patent claims: 1. Battery ignition system with one ignition coil and one in the primary circuit of the ignition coil Transistor made by one in its base-collector-Kxeis arranged interrupter is controlled from the conductive to the non-conductive state, and with an emitter-base path of the transistor bypassing the parallel circuit, the one magnetically against the Ignition coil contains decoupled inductance, thereby characterized in that the inductance (39) with a rectifier (40) in series is connected, the rectifier together with the emitter-base path of the transistor (31) has the same forward direction and is conductive when the breaker is closed. 2. Battery ignition system according to claim 1, characterized in that parallel to the Induk- a.i activity (39) a capacitor (42) is provided. 3. Battery ignition system according to claim I and 2, characterized in that one in series with the inductance (39) and the rectifier (40) Limiting resistor (41) is provided.