DE1931236C3 - Ignition system for internal combustion engines - Google Patents

Description

35

The invention relates to an ignition system for internal combustion engines with an ignition transformer, the output side in an ignition circuit containing at least one spark plug and both the input side in the one electronic discharge switch containing discharge circuit of an ignition capacitor as well as in one leading directly to a voltage source, an electronic opening switch containing direct current circuit, wherein the sequence of an ignition process is accomplished in such a way that that the discharge switch in the current-conducting state, on the other hand, the opening switch in the current-blocking state State is controlled to electrical energy stored in the ignition capacitor and in the ignition transformer stored magnetic energy jointly in the generation of the ignition circuit certain ignition voltage to participate.

Such an ignition system ensures that the spark plug is very dirty and inhomogeneous Fuel-air mixture certainly produces an effective spark.

There are already basic circuits for such ignition systems (e.g. according to US Pat. No. 32 80 809) known, however, with regard to the control of the ignition process, not yet a satisfactory solution show. For example, in an ignition system that can be removed there, which according to the is electronically controlled according to modern requirements, the control circuits of the discharge switch and the opening switch are connected to the ignition capacitor in such a way that that the charging current pulses fed to the ignition capacitor can easily trigger incorrect switching.

The invention is therefore based on the object of providing an ignition system of the type mentioned at the beginning create, which also works satisfactorily with regard to the control of the ignition process.

This object is achieved according to the invention in that when the previously charged ignition capacitor discharges in the current-carrying state of the discharge switch, one generated in the ignition transformer Voltage for reversing the opening switch belonging to the DC circuit to the current-blocking one State is used up.

Details that further develop the invention are based on the exemplary embodiment shown in the drawing explained and described in more detail.

It shows

Fig. 1 shows an ignition system with the exception of the Control electrodes of the discharge switch and the opening switch to be connected control circuit,

F i g. 2 the control circuit to be connected to the control electrodes of the discharge switch and the opening switch and

3 to 5 different insertions of the ignition transformer in the circuit arrangement of the Ignition system.

The ignition system according to Fi g. 1 is for an internal combustion engine determined and contains an ignition transformer 11, the output side, d. H. with its secondary winding 12, in which an ignition circuit containing a spark plug 13 is located. Of course you can at It is known that a plurality of spark plugs can also be provided, which are replaced by a not shown Ignition distributor can be connected to the ignition circuit at the required time.

On the input side, the ignition transformer 11 has a main winding 14 and a storage winding 15, both of which sit on an iron core 16 together with the secondary winding 12. The main winding 14 lies in a discharge circuit belonging to an ignition capacitor 17, which can be closed and opened by means of a discharge switch 18. A controllable rectifier, preferably a thyristor, is selected as the discharge switch 18, the anode A 1 of which is connected to the ignition capacitor 17 and its cathode K 1 to the main winding 14. The connection point 19 located between this cathode K 1 and the main winding 14 is connected to a positive line 20 belonging to a direct current circuit, which is connected to the positive pole of a voltage source 22, e.g. B. the battery belonging to a motor vehicle can be connected. On the other hand, the connection point 23 located between the anode A 1 and the ignition capacitor 17 is connected to the positive output 24 of a DC voltage converter 25 delimited by a dash-dotted line.

The DC / DC converter can be a single-ended converter known per se or also a per se well-known push-pull converter. In the preferred example, a push-pull converter is selected that is connected to its output has four rectifiers 27, 28, 29, 30 located in a bridge circuit 26 Bridge circuit 26, with its two input connections 31, 32, is one on secondary winding 33 Converter transformer 34 connected, while the positive output 24 at the connection point 23 and the negative output 35 are connected to a negative line 36 belonging to the direct current circuit, which is connected to the

The negative pole of the voltage source 22 and is connected to ground at the same time. The secondary winding 33 of the Converter transformer 34 sits on an iron core 37, which also has a primary winding 38 and two Feedback windings 39,40 carries. The feedback windings 39,40 are at one end via a Line 41 connected directly to one another, while the other end of these windings 39,40 over one of two diodes 42, 43 is led to the base 44 and 45, respectively, one of two transistors 46, 47. The to Emitters 48, 49 of these transistors 46, 47 are connected to one another by a line 50, wherein this line 50 is also connected to the negative line 36 and to the anodes of two diodes 51, 52 The diode 51 is just like the diode 42 with its cathode on the base 44 of the transistor 46 and the Diode 52 as well as diode 43 with its cathode at base 45 of transistor 47. Furthermore, the transistor 46 with its collector 53 to one end of the primary winding 38 and the transistor 47 with its Collector 54 connected to the other end of primary winding 38. The primary winding 38 has a center tap 55, which is connected to the positive line 20

Connected to the positive output 24 of the DC voltage converter 25 is a monitoring device 56 that controls the voltage occurring there and is bordered by a dash-dotted line and is used to shut down the DC voltage converter 25 when this voltage exceeds a certain value DC-voltage converter 25 outgoing connection line 57 leading to the monitoring device 56 is connected to the base 59 of a transistor 60 via a resistor 58. A connection also leads from the base 59 of the transistor 60 to the negative line 36, which connection contains a temperature-dependent resistor 61 with a negative temperature coefficient, to which a resistor 62 is connected in series and a resistor 63 is connected in parallel. The emitter 64 of the transistor 60 is connected to the anode of a diode 65 lying with the cathode on the minus line 36 and to the emitter 66 of a transistor 67. The collector 68 of the transistor 60 is connected via a resistor 69 to the plus line 20 and via the a capacitor 70 and a resistor 71 existing parallel connection at the base 72 of the transistor 67. The collector 73 of the transistor 67 is connected via a resistor 74 to the base 76 belonging to a transistor 75, which is also connected via a capacitor 77 and a resistor The parallel circuit containing 78 is connected to the plus line 20. The transistor 75 is connected at its emitter 79 directly to the plus line 20 and at its collector 80 via a resistor 81 to the line 41 belonging to the DC / DC converter 25.

The ignition transformer 11 lies with its storage winding 15 in a dc circuit, the closed operating switch 21 Upper positive lead 20 and the negative line 36 is connected to the voltage source 22. The storage coil 15 is connected to one end of «n the connection point 19 and thus connected to the positive line 20 , while a connection leads from its other end to the negative line 36, which contains an electronic opening switch 83 , preferably connected in series with a limiting resistor 82, as opening switch 83 is also a controllable rectifier, preferably a thyristor with its anode A 2 the storage winding 15 and with its cathode K 2 facing the negative line 36

The principle of the ignition system is based on the fact that when an ignition process is running, the discharge switch 18 is switched to the current-conducting state, whereas the opening switch 83 is switched to the current-blocking state, so that electrical energy stored in the ignition capacitor 17 and magnetic energy stored in the ignition transformer 11 are jointly generated the ignition voltage determined for the ignition circuit. In order to achieve this, a voltage generated in the ignition transformer 11 by the discharge of the ignition capacitor is used to switch the opening switch 83 to the current-blocking state. This voltage is used in such a way that it is opposite to the voltage normally present at the anode / 4 2 and cathode K 2 , supplied by the voltage source 22 and consequently the voltage required for the conductive state of the anode-cathode path A2-K2 Anode voltage cancels In the example, the voltage used for reversing the opening switch 83 into the current-blocking state is a voltage induced by the main winding 14 on the storage winding 15. It has proven to be advantageous if the main winding 14 and the storage winding 15 have at least approximately the same number of turns. Furthermore, it has proven to be advantageous if the capacitance of the ignition capacitor 17 is selected to be greater than the sum of the capacitances present on the output side of the ignition transformer 11 and transferred to the main winding 14.

It is also recommended that the opening switch 83 consists of a resistor 84 and a capacitor 85 existing series circuit to be connected in parallel. It has also proven to be beneficial to the Opening switch 83 to put a shunt branch, which has a voltage stabilizing member 86, z. B. a so-called VDR resistor, or - as indicated with dashed lines - the one from one Capacitor 87 and a resistor 88 contains existing parallel connection Shunt branch a diode 89 can be inserted, which is used by the switch 83 for reversing the opening switch In the current blocking state serving voltage is claimed in the reverse direction.

In Fig. 2 is one for the ignition system according to FIG. 1 particularly suitable control circuit is shown there, the controllable rectifier used as discharge switch 18 is connected to its control electrode 51 via a connection containing a first control resistor 90 to the positive line 20 and via a connection containing a first control capacitor 91 to a second control resistor 92 located on the negative line 36. A capacitor 93 can be connected in parallel to the first control resistor 90 and a limiting resistor 94 can be provided in the connection leading from the control electrode S1 to the first control capacitor 91.From the connection point 95 between the second control resistor 92 and the first control capacitor 91 leads to the positive line 20 a connection which includes the emitter-collector path El-Cl belonging to a first transistor Tl (of the pnp type). The base Bl of the first transistor Tl is connected to the one not shown

Internal combustion engine-coupled circuit breaker 96 in operative connection that by opening this breaker switch 96, the emitter-collector path Ei-Ci is controlled in the current-carrying state.

One connection of the breaker switch 96 is connected to the negative line 36 and the other connection is connected to the positive lead 20 via a resistor 97 which causes a contact cleaning current is at a connection point 100. This connection point 100 lies between a resistor 101 connected to the positive line and a Zener diode 102 connected with its anode to the negative line 36, which is expediently connected in parallel with a capacitor 103.The connection point 104 between the diode 98 and the resistor 99 is via a rated resistor 105 connected to the base B 2 of a second transistor 72 (of the npn type). This transistor 72 is connected at its emitter E2 to the anode of a stabilization diode 106 which is connected with its cathode to the base Bl addition, this transistor T2 is connected at its collector C 2 at the connection point 100 and at its emitter E 2 nor to the anode of a Diode 107 is connected, which is connected at its cathode via a first charging resistor 108 to a second control capacitor 109 lying on the negative line 36. The first charging resistor 108 has the series circuit consisting of a second charging resistor 110 and a third control capacitor U1 in its shunt and at its connection facing the second control capacitor 109 with the anode of a diode 112 which is connected to its cathode via a discharge resistor 113 at the resistor-side connection of the breaker switch 96 is located. The second control capacitor 109 is connected to the terminal facing the negative line 36, both via a capacitor 114 with collector C3 and via a resistor 115 with the emitter £ 3 of a third transistor 7 "3 (of the npn type) Connection, while its other terminal is connected to the base A3 of this transistor 73 via a resistor 116. In addition, the emitter £ 3 is connected to the anode of a diode 117 connected to the base B 3 and via a rated resistor 118 to the connection point 100. The collector C3 of the The third transistor T3 is also connected to a rated resistor 119 connected to the junction 100 and to a capacitor 120 operating as a differentiating element, the other connection of which is connected via a rated resistor 122 to the base B 4 of a fourth transistor Γ4 (of the npn type) Base B 4 is also at a rated resistor 123 located at connection point 100 and connected to the cathode of a stabilizing diode 124 connected to the negative line 36. In addition, the fourth transistor 74 is directly connected to the negative line 36 at its emitter EA and to its collector CA to a resistor 125 connected to the connection point 100 and to the base ¹ BS of a fifth transistor 75 (of the npn type). The transistor 75 is at its emitter E5 also directly on the negative line 36 and on its collector C5 is connected to a rating resistor 126 located on the positive line 20 and to a rating resistor 127 located on the base Bi of the first transistor 71.

S The closing of the circuit breaker 96 is exploited in the present example for reversing the controllable rectifier used as opening switch 83 into the current-carrying state. As a result, leads from the resistance side

ίο Connection of the interrupter switch 96 a connection to the cathode of a decoupling diode 128, the anode of which is connected via a rated resistor 129 to the base B 6 of a sixth transistor 76 (of the pnp type). This base B 6 is also made on the

ι S a design resistor 130 and one for Discharge of interfering waves serving capacitor 131 existing parallel connection to the connection point 100 connected. Furthermore, the emitter E6 of this transistor 76 is also at the connection point 100 connected. The collector C6 of the sixth transistor 76 is connected to one on the negative line 36 Rated resistor 132 and connected to a fourth control capacitor 133. This control capacitor 133 is at its other terminal with a Rated resistor 134 lying on negative line 36 and with the anode of a charging diode 135 connected. The cathode of this diode 135 is connected to a third charging resistor 136 and a fifth Control capacitor 137 containing series circuit with the negative line 36 in connection, this series circuit 136, 137 has two series-connected resistors 138, 139 in its shunt, the common connection point 140 of these two resistors 138, 139 at the base B 7 of a seventh transistor 77 is (npn type) and via a capacitor 141 containing compound at the same time connected to the negative line 36 emitter El of the transistor 77th The collector C 7 of the seventh transistor 77 has two via the series connection Resistors Resistors 142, 143 connection to the positive line 20. The common connection point 144 of these two resistors 142, 143 is at the base B 9 of an eighth transistor 78 (of the pnp type) and via a capacitor 145 to the positive line 20, which is also connected to the emitter E8 of this transistor 78. The collector CS of this transistor 78 is connected to the negative line 36 via the series connection of two resistors 146, 147, whose common connection point 148 is on the control element trode 52 of the used as opening switch 83 controllable rectifier and is also connected to the negative line 36 via a capacitor 149

If necessary - as shown in the example - to that of the operating switch 21 and the voltage source 22 existing series connection still has one Zener diode 150 can be connected in parallel.

The ignition system works as follows: Used to start the internal combustion engine the operating switch 21 is closed, so begins the To oscillate DC voltage converter 25 in a known manner, whereby at the output 24, 35 dei Rectifier bridge circuit 26 a pulsating! Direct current occurs, which aul the ignition capacitor 17 High-voltage potential charges this high-voltage

voltage potential is controlled by the monitoring device 56 before the high voltage potential can assume a dangerous value, the base 59 of the transistor 60 is so far positively biased that £

the emitter-collector path 64-68 goes into the current-carrying state. This has the consequence that the emitter-collector path 66-73 of the transistor 67 and thus also the emitter-collector path 79-80 of the transistor 75 is controlled in the current blocking state. The emitter-collector path 79-80 of the transistor 75 interrupts the of the Plus line 20 outgoing, over the resistor 81 to the cable 41 outgoing connection, so that the DC voltage converter 25 is automatically taken out of service until the high voltage potential has fallen back to a normal value and the the aforementioned reversal of the transistors 60, 67, 75 has been reversed.

An ignition process is triggered by opening the interrupter switch 96, which then causes the base S 2 of the second transistor T2 to be connected to the potential necessary for reversing the emitter-collector path E 2 - CI into the current-conducting state. The second control capacitor 109 and the base B 3 of the third transistor are charged via the resistor 101, the conductive emitter-collector path E2-C2, the diode 107 and both the first charging resistor 108 and the second charging resistor 110 and the third control capacitor 111 T3 so far positively biased that its emitter-collector path E3-C3 gets into the current-carrying state. With the help of the capacitor used as a differentiating element 120, a negative voltage spike is generated, which reaches the base BA of the fourth transistor TΛ and controls its emitter-collector path E4-C4 in the current-blocking state. As a result, the potential at the base B 5 of the fifth transistor 7-5 rises so far in the positive direction that its emitter-collector path E5-C5 is conductive and the base B1 of the first transistor Tl supplies a potential through which the The first control capacitor 91 previously charged via the first control resistor 90, the limiting resistor 94 and the second control resistor 92 can now be via the first control resistor 90, the limiting resistor 94 and the conductive emitter-collector path of El-Cl of the first transistor Tl discharged in such a manner that the employed as a discharge switch 18 controllable rectifier the control electrode Sl as the cathode K 1, and thus the Schaltstrekke A 1 positive - K 1 is conductive. In this case, the ignition capacitor 17 discharges via the main winding 14, as a result of which an ignition voltage with a rising edge is induced in the secondary winding 12. Simultaneously with this, however, a voltage is also induced in the storage winding 15, which is opposite to the voltage of the voltage source 22 and causes this switching path A2-K2 to be interrupted at the anode-cathode path A2-K2 of the controllable rectifier used as opening switch 83. The magnetic energy stored by the storage winding 15 now also causes an ignition voltage in the secondary winding 12. Care must be taken here that the duration during which the counter voltage occurs on the anode-cathode section A2-K2 is greater than the deionization time of this section A 2 -K 2

Optimal results in terms of the energy transfer rune and also in terms of the ignition voltage that can be generated voltages in the ignition transformer 11 are obtained when the which initially occurs in the secondary winding 12 and is dependent on the stored electrical energy Voltage half-wave negative polarity and the associated

S subsequently occurring there, both from the stored as a result of charge reversal of the ignition capacitor 17 electrical energy as well as voltage half-wave dependent on the stored magnetic energy positive polarity is achieved in this way that this

ίο at least approximately two voltage half-waves can be made equal in value. In addition, they are also saved by the Magnetic energy-dependent secondary sparks at the spark plug 13 are present in sufficient quantities.

is the one from resistor 84 and capacitor 85 existing series circuit in the shunt of the opening switch 83 avoids dangerous high voltage peaks when it is switched off. Through the Coupling of the storage winding 15 with the main winding This protection also works for the discharge switch 18. The voltage stabilizing member 86 prevents dangerously high levels when the ignition circuit is open Voltage values can be achieved. The same can be said of the capacitor 87 and the resistor 88 existing parallel connection. The diode 89 is intended to unnecessarily dampen the ignition voltage avoid.

If the interrupter switch 96 is now closed again, the emitter-collector section ke E2-C2 of the second transistor T2 back into the Current-blocking state controlled As a result, the second control capacitor 109 can both via the Diode 112, resistor 113, breaker switch 96 and negative line 36 as well as via the Resistor 116, the base-emitter path £ 3- £ 3 of the third transistor T3 and the resistor 115 are discharged. The last-mentioned discharge branch 116, B3-E3, 115 ensures that the emitter-collector path Ei-Ci of the third transistor T3 for the time being remains conductive Under these conditions, opening the circuit breaker 96 as a result of bouncing its contacts triggered no negative voltage spike at the differentiating element 120 and consequently the discharge switch 18 not in the undesired time point controlled in the current-carrying state will. The charging resistor 108 connected in series with the capacitor 109 ensures that the protection against Interrupter bouncing is more satisfactory even at very different speeds of the internal combustion engine

Way is effective

The second charging resistor UO and the third connected in parallel with the first charging resistor 108 Control capacitor 111 containing series circuit ensures that the threshold voltage at the base Emit ter path Bi-Ei of the third transistor T3 very reached quickly and the emitter-collector route £ 3 — C3 of this transistor T3 without essential

Delay into the conductive state is controlled. By the connection point 100 via the

Resistor 118, the diode 117 and the resistor IU leading to the second control capacitor 109 connection, this capacitor 109 is always about: charged, so that the reversal of the emitter-collector path Ei-Ci of the third transistor Ti nich is delayed.

Furthermore, when the breaker closes switch 96 but also the base £ 6 of the sixth transistor T6 so far negatively biased that dessei

Emitter-collector path E6-C6 becomes conductive and as a result of the fourth control capacitor 133 provided a positive pulse occurs at the cathode of the charging diode 135. This pulse causes a charging current to flow in the fifth control capacitor 137 and the third charging resistor 136 and at the same time such a potential at the base Bl of the seventh transistor Tl, that its emitter-KoUektor-path El-Cl gets into the conductive state. This has the consequence that the base B Λ of the eighth transistor Γ8 is strongly negative and its emitter-collector path ES- CS also goes into the conductive state. A voltage then drops across resistor 147, through which the controllable rectifier used as opening switch 83 becomes positive at its control electrode 52 with respect to cathode K 2 and again at its switching path A 2-K2 for the flow of the The direct current supplied by the voltage source 22 is ready s interrupter switch 96 are disturbed, then the fifth control capacitor 137 temporarily supplies the necessary control energy to the base B 7 of the seventh transistor Tl as a substitute for maintaining the through-control process, so that in this case too, control potential is available at the control electrode 52 for switching on the opening switch 83 stands

The data at connection point 100, i.e. H. so about the Resistor 101 connected to positive line 20 Circuit elements received in comparison to the Voltage at the voltage source 22 has a lower voltage, but which is stabilized and consequently also In the event of fluctuations in the voltage at the voltage source 22, the system can still work smoothly The capacitor 103 serves to divert interference pulses.

The use of the Zener diode 150 is an additional protective measure against in the on-board network voltage peaks occurring at other consumers.

The ignition system can also be designed so that the function of the main winding 14 and that of the storage winding 15 (Fig. 1) from a single one Main winding 14 are met, as shown in Fig.3 that facing away from the connection point 19 The end of the main winding 14 is then both with the ignition capacitor 17 and possibly below Interposition of the limiting resistor 82 with the anode Λ 2 of the opening switch 83 used controllable rectifier to connect. The connection leading to the opening switch 83 but can also be at a tap 151 of the single main winding 14 located between the winding ends be connected (Fig. 4). But it is also possible to replace the main winding 14 after the connection point of the ignition capacitor 17 by an additional winding 14 ' continue and the lead to the opening switch 83 connection to the free end of this Additional winding 14 'to be connected (FIG. 5).

For this purpose 3 sheets of drawings

Claims (33)

Patent claims: 1. Ignition system for internal combustion engines with an ignition transformer, the output in one at least one ignition circuit containing a spark plug and on the input side both in the one electronic discharge switch containing discharge circuit of an ignition capacitor as well as in a direct current circuit which leads directly to a voltage source and contains an electronic opening switch, the sequence an ignition process is accomplished in such a way that the discharge switch is in the current-conducting State, on the other hand the opening switch is controlled in the current-blocking state to in Ignition capacitor stored electrical energy and magnetic energy stored in the ignition transformer together to generate the for to attach the ignition circuit to the specific ignition voltage, characterized in that, when the previously charged ignition capacitor (17) discharges in the current-carrying state of the discharge switch (18), a voltage generated in the ignition transformer (11) is used to reverse the the opening switch (83) belonging to the direct current circuit is used in the current-blocking state is. 2. Ignition system according to claim 1, characterized in that a controllable rectifier located in the direct current circuit with its anode-cathode path (A 2-K 2) is used as the opening switch (83) and that the ignition transformer (11 ) taken voltage is opposite to the voltage normally present on the DC circuit. 3. Ignition system according to claim 1 and 2, characterized in that the ignition transformer (U) has a main winding (14) shunted to the series circuit consisting of the discharge switch (18) and ignition capacitor (17) and that this main winding (14) also with the anode (A 2) of the controllable rectifier used as opening switch (83) has connection, whereas its cathode (K 2) is connected to the negative line (36) of the direct current circuit. 4. Ignition system according to claim 3, characterized in that one end of the main winding (14) is connected to the positive line (20) of the direct current circuit and that this end is connected to the anode (A 2) via a storage winding (IS) also belonging to the ignition transformer (U) ) of the controllable rectifier used as opening switch (83) has connection. 5. Ignition system according to claim 4, characterized in that the main winding (14) and the Storage winding (15) have at least approximately the same number of turns. 6. Ignition system according to claim 3 or 4, characterized in that the ignition transformer (11) <*> The sum of the capacities present on the output side and transferred to the main winding (14) is selected to be smaller than the capacitance of the ignition capacitor (17). 7. Ignition system according to one of claims 1 to 4, characterized in that the opening switch (83) a series circuit consisting of a resistor (84) and a capacitor (85) in parallel lel is switched 8. Ignition system according to one of claims 1 to 4, characterized in that the opening switch (83) has a shunt branch in which a voltage stabilizing member (86) is located 9. Ignition system according to one of claims 1 to 4, characterized in that the opening switch (83) has a shunt branch in which there is a resistor (88) connected in parallel to a capacitor (87) 10. Ignition system according to claim 8 or 9, characterized in that the shunt branch üei a diode (89) is connected to the opening switch (83] 11. Ignition system according to claim 3, characterized in that the end of the main winding (14) lying on the ignition capacitor (17) has a connection with the anode (A 2) of the controllable rectifier used as an opening switch (83) 12. Ignition system according to claim U, characterized in that the end of the main winding (14) lying on the ignition capacitor (17) via an additional winding (14 ') also belonging to the ignition transformer (U) with the anode (A 2) of the opening switch ( 83) used controllable rectifier connection. 13. Ignition system according to claim 3, characterized in that the main winding (14) is connected to the anode (A 2) of the controllable rectifier used as an opening switch (83) via a tap (151) located between its two winding ends. 14. Ignition system according to at least one of claims 3 to 13, characterized in that a limiting resistor (82) is located in the connection leading from the main winding (14) to the anode (A 2) of the controllable rectifier used as an opening switch (83). 15. Ignition system according to claim 1 to 4, characterized in that the discharge switch (18) is also a controllable rectifier with the cathode (K 1) on the positive line (20) of the direct current circuit and with the anode (A 1) together with the Ignition capacitor (17) is connected to the positive output (24) of a DC voltage converter (25], the negative output (35) of which leads to the negative line (36) of the direct current circuit and whose input is fed by the same voltage source (22) as the direct current circuit. 16. Ignition system according to claim 14, characterized in that the DC voltage converter (25) is designed as a push-pull converter and at its output four in a bridge circuit (26] has horizontal rectifiers (27,28,29,30). 17. Ignition system according to claim 15 and 16, characterized characterized in that at the output (24) of the DC voltage converter (25) there is one Voltage controlling monitoring device (56) is connected, which to the outside Operation of the DC voltage converter (25) is then used when this voltage is a exceeds a certain value. 18. Ignition system according to claim 1 and at least; one of claims 2 to 17, characterized in that one is coupled to the internal combustion engine Interrupter switch (%) is used to control the ignition process. 19. Ignition system according to claim 15 and 18, characterized characterized in that the controllable rectifier used as discharge switch (18) is connected to its control electrode (Si) via a connection containing a first control resistor (90) to the positive line (20) and via a connection containing a first control capacitor (91) to a connection to the negative line (36) lying second control resistor (92) is connected, whereby of the connection point (95) lying between the first control capacitor (91) and the second control resistor (92) to the positive conductor (20) another, the switching path ffl-C1) one first transistor (Ti) containing connection leads and this switching path (Fl-Cl) can be controlled by opening the interrupter switch (96) in the current-carrying state 20. Ignition system according to claim 18 and 19, characterized in that the switching path (E2-C2) of a second transistor (T2) can be controlled in the current- conducting state by opening the interrupter (96) and that this switching path (E2-C2) in one Connection is that leads from the positive line (20) to one connection of a second control capacitor (109), the other connection of which is connected to the negative line (36) and in the shunt has a circuit branch that connects the control path (S3 - £ 3) a third transistor (T3) whose switching path (E3-C3) is kept in the current-conducting state both by the charging current and by the discharging current of the second control capacitor (109) until shortly before the opening time of the interrupter switch (96) and with a differentiating element (120) is in connection, from which that voltage peak that occurs when the switching path (E3 - C3) of the third transistor (T3) becomes conductive is taken and is used to reverse the switching path (Ei-Ci) of the first transistor (Ti) in the current-carrying state. 21. Ignition system according to claim 20, characterized in that the interrupter switch (96) is in a connection leading from the negative line (36) to the control electrode (B 2) of the second transistor (T2). 22. Ignition system according to claim 20 or 21, characterized in that in the of the switching path (E2-C2) of the second transistor (T2) to the second control capacitor (109) leading connection is a first charging resistor (108), which is preferably with a the charging current for the second control capacitor (109) passing diode (117) is connected in series. 23. Ignition system according to claim 22, characterized in that shunted to the first Charging resistor (108) is a series circuit consisting of a second charging resistor (110) and a third control capacitor (111). 24. Ignition system according to claim 22 or 23, characterized in that the second control capacitor (109) with its the first charging resistor (108) facing connection via a from a discharge current passing diode (112) and a discharge resistor (113) existing series circuit on the with the control electrode '15 (B 2) of the second transistor (T2) connected terminal of the interrupter switch (96). 25. Ignition system according to one of claims 20 to 24, characterized in that the circuit branch containing the control path (B3-E3) of the third transistor (T3) is connected to the two connections of the second control capacitor (109) via a resistor (115 or 116) and that this control path (B3 -E3) a diode (117) blocking the discharge current of the second control capacitor (109) is connected in parallel and also has a connection to the Pius line (20) at its anode via a resistor (118) 26. Ignition system according to one of claims 20 to 25, characterized in that with the help of the voltage peak taken from the differentiating element (120) the switching path (E4-C4) of a fourth transistor (T4) in the current-blocking state and, depending on this, the switching path (E5-CS) of a fifth transistor (TS) can be controlled in the current-conducting state, the switching path (E5-C5) of the fifth transistor (T5) being in a control connection connected to the control electrode (B 1) of the first transistor (Tl), which is the switching path (Ei-Ci) of the first transistor (Ti) leads into the conductive state controlling potential 27. Ignition system according to one of claims 19 to 26, characterized in that the control electrode (Sl) of the discharge switch (18) used controllable rectifier to the second control resistor (92) leading connection a resistor (94) connected in series with the first control capacitor (91). 28. Ignition system according to claim 18, characterized in that the closing of the interrupter switch (96) for reversing the as Opening switch (83) used controllable rectifier in the current-carrying state is exploited 29. Ignition system according to claim 28, characterized in that the terminal of the interrupter switch (96) facing away from the negative line (36) has a connection to the control electrode (Bb) of a sixth transistor (T6) and the switching path (E6-C6) of this transistor (T6 ) is in a connection from the positive line (20) to a fourth control capacitor (133), the other terminal of which is connected to the anode of a charging diode (135), the cathode of which has a fifth control capacitor (137) and a third charging resistor (136) containing series circuit has connection with the negative line (36) and is used to extract a control pulse which is suitable for reversing the controllable rectifier used as opening switch (83) into the current-carrying state. 30. Ignition system according to claim 28 and 29, characterized in that the series circuit containing the fifth control capacitor (137) and the third charging resistor (136) has a shunt branch which contains the control path (B7-E7) of a seventh transistor (T7) Switching path (ET-Cl) is connected to the control path (B8-ES) of an eighth transistor (TS) in such a way that when the control pulse occurs, the switching path (E7-C7) of the seventh transistor (T7) and, depending on it, the switching path ( ES - C8) of the eighth transistor (TS) enters the current-conducting state, whereby the switching path (E9-C8) of the eighth transistor (TS) is in a connection leading from the positive line (20) via two series-connected resistors (146, 147) to the negative line (36) and at the connection point (148) of these two resistors (146, 147) the control electrode (S 2) of the controllable rectifier used as opening switch (83) is connected. 31. Ignition system according to one of claims 20 to 27, 29, 30, characterized in that from the second transistor (T2), the third transistor (T3), the fourth transistor (T4) and the sixth transistor (T6) outgoing to the Connections carrying the positive line (20) run jointly via a resistor (10i), the connection of which, facing away from the positive line (30), is connected via a voltage-stabilizing switching element (102), e.g. B. has a Zener diode with the negative line (36) connection. 32. Ignition system according to claim 31, characterized in that the voltage-stabilizing switching element (102) has a capacitor (103) connected in parallel. 33. Ignition system according to one of claims 18 to 30, characterized in that the terminal of the interrupter switch (96) facing away from the negative line (36) is connected to the positive line (20) via a resistor (97) and is connected to the control electrode (B 2) of the second transistor (T2) and the control electrode (B 6) of the sixth transistor (T6) to these connections leading to connections each have a decoupling diode (98 or 128) is provided.