DE1956813B2 - IGNITION CIRCUIT FOR A IGNITION SYSTEM FOR COMBUSTION MACHINES - Google Patents

Description

The invention relates to an ignition circuit for an ignition system for internal combustion engines in which from an ignition signal generator via at least two control circuits two with a delay one after the other Discharges are triggered.

In a known embodiment (British patent specification 994 712) the first discharge occurs when the Voltage of a charging capacitor reaches the flashover value of a gas discharge tube. There but all parameters of the ignition circuit have fixed values, there is a constant delay up to; second discharge. Although this delay can be adjusted by itself, it is not dependent on the speed Internal combustion engine dependent. The delay between the two discharges is, however, in reciprocating internal combustion engines of crucial importance, since different speeds result in different Operating conditions for the combustion uni result.

ίο The invention is based on the object of a Further develop the ignition circuit of the type mentioned in such a way that the delay between the two Discharges is dependent on the engine speed and decreases with increasing speed

This object is achieved according to the invention by a converter with a primary winding and a Secondary winding connected to terminals of the circuit with opposite polarity are, a transistor with a control electrode and two current-carrying electrodes, wherein the current-carrying electrodes are connected to a direct current source in series with the primary winding, and by a capacitor and two resistors, with one ÄC charging circuit for the capacitor at least the capacitor, one resistor, the control electrode of the transistor and one of the current-carrying ones Electrodes of the transistor in series between the direct current source and a second Contains switching device, and the second switching device at each occurring at the terminals Ignition signal the capacitor with opposite polarity with its control electrode and one its two current-carrying electrodes connects to a discharge circuit for the capacitor across the second resistor to close. The inventive design of the ignition circuit is a more perfect combustion achieved in all operating situations, especially with regard to exhaust gas decontamination is essential.

In a further embodiment of the invention it is provided that the second switching device is a second Transistor with a base electrode, an emitter electrode and a collector electrode, which is with the base-emitter circuit is connected to the terminals of the signal generator and its collector electrode Via the first resistor to the direct current source and to the one lining of the Capacitor is connected, the other side of which is connected to the direct current source via the second resistor and is connected to the control electrode of the first transistor.

Furthermore, the invention is characterized by an on the charging current of the ignition capacitor high engine speed responsive signal suppression circuit, the one parallel to Forms converter circuit lying path for the second of the switching signals supplied with each ignition signal.

In the drawing, circuit diagrams of ignition circuits according to the invention are shown. In the drawing is

F i g. 1 is a circuit diagram of an ignition system according to the invention using a conventional ignition distributor with break contacts and

F i g. 2 is a circuit diagram of an ignition system with a magnetic ignition distributor.

In the drawings, the same reference numerals are used for the same components.

Generally, both ignition systems contain ignition locks. An excitation circuit for the primary winding capacitor, an ignition signal generator, which supplies a first control speed of the internal combustion engine matched to the development 27 of the converter 36. Ignitable switching device for connecting and disconnecting signals, one to each ignition signal, the positive side of the direct current source . Furthermore, a circuit is provided to two switching signals of the same 5, a timing circuit to form the input circuit polarity, a converter circuit that connects to each and the controllable switching device, switching signal responds to the charging voltage for the switching device to the ignition capacitor after a certain time to form, and an output circuit based on a supplied ignition signal in which the discharge of the ignition capacitor reverses polarities,
tor through the primary winding of the ignition coil at each io The primary winding 37 of the converter 36 is carried out with the output signal of the converter circuit. The usual storage battery 8 connected to its side 46 via a resistor 44 and a single circuit of the ignition system are supplied by a diode 45 connected to the output terminal 28 and with its side 47 via a conductor 48, the signal transmitter is removable in the ignition system according to FIG Contact arm 57 of a switch 56 and which are connected to ground 5 by two breaker contacts 10 imd 10 α of a 15 direct current source 8. The secondary ignition interrupter is formed, which in the independent winding 38 of the converter 36 is connected to the output terminal 28 from its side 58 via a connector based on the speed of the internal combustion engine, for which purpose a known capacitor 54 and a diode 55 are connected and with Way, a rotating cam is used. At the ignition of their side 59 connected to ground 5 via a conductor 64, system according to FIG. 2 is an electro 20 as a signal transmitter so that it is used with a magnetic distributor opposing the primary winding 37, which is connected from a set polarity. The positive pole piece 12 for the formation of a field and an off-side of the primary winding 37 is therefore formed in the sub-releasing coil 14, which is wound around an armature 15 provided with the output terminal 28 with cams of the excitation circuit. The armature 15 is connected, while the other side is connected to ground 5, depending on the speed of the internal combustion engine 25, while the positive polarity engine is driven and supplies ignition signals in the secondary winding 38 side when switching on in a manner known per se. The current-dependent wall excitation circuit for the primary winding 37 with the lerkreis contains a converter 24 with a primary output terminal 28 is connected, while its anwick 25 and Einei secondary winding 26. The other side is connected to ground 5.

Primary windings 25 are parallel to one another Control resistors 30 and 31 in series so terminals 16 and 17 and the first controllable one as a normally non-conductive npn-Schalt- switching device is designed so that he transistor 40 with a control electrode and two transistors 80 after a certain time in live electrodes. This circle is to which the initial state switches back, like this still DC power source 8 connected. Furthermore, a 35 will be explained later. Includes dci timing circuit Switching circuit for forming a switching signal in resistors 67 and 68 and a capacitor 69 Depending on each ignition signal provided, the and a second controllable switching device. These a normally non-conductive npn-Umschalt- can be designed as an npn transistor 90, which is on contains transistor 50 with associated circle. One for each ignition signal applied to terminals 16 the pressure drop appears in the control resistors 30 and 40 and 17, responds to the capacitor 69 31 responsive control circuit for switching off the one with opposite polarity via the base switching circuit to connect when reaching a Spanmingsab- emitter circuit of the transistor 80 and if so certain size in the control resistors with a discharge circuit for the capacitor 69 to consists of two normally conductive npn- connections.

Transistors 60 and 70, which are in Darlington connection 45 The excitation circuit for the primary winding 37 of the are arranged and the associated circle. As mentioned, a converter 36 is an npn transistor 80 Another circuit, consisting of resistors lying in series with a base electrode 81, a collector electrode 33, 34 and 35 is used to feed the 82 and an emitter electrode 83. The primary Wickan the control resistors 30 and 31 entering development 37 and the current-carrying collector-emitter voltage drop to the control circuit. 5 ° circuit of the transistor 80 are in series with the The output circuit contains an ignition capacitor DC source 8 when the switch 56 is closed-18 with assigned charging circuit, which is primary winds. the connection being through a resistor treatment 20 of a conventional ignition coil 19, which connects a second 74, the conductor 48 and the switch 56 to ground 5 The winding 21 has an ignition capacitor.

gate switch 22 in the form of a controlled silicon 55 A charging circuit for the capacitor 69 consists

rectifier, the ignition capacitor 18 with the resistor 67, the capacitor 69 and

Primary winding 20 connects the ignition coil. the base-emitter circuit of the transistor 80 and is

The circuit for forming two switching signals between the positive conductor 48 and ground 5.

same polarity depending on each ignition The collector-emitter circuit of transistor 90

signal consists of an input circuit to which there is over 60 at a connection point 75 between the con-

the terminals 16 and 17, the ignition signals capacitor 69 and the resistor 67 and the with

are fed, and an output circuit, dei a ground 5 connected emitter electrode 83 of the

Output terminal 28 and a ground terminal 5 on transistor 80.

shows. The circuit also includes a converter 36. The resistor 68 is connected to the base electrode 81

with a primary winding 65 of the transistor 80 and the emitter electrode 93 of the

37 and a secondary transistor 90 located in the output circuit and is connected to the positive

winding 38, which with opposite pole conductors 48, the switch 56 and the direct current

larity to the output terminals of the eye source circuit 8 to earth 5.

The base-emitter circuit of the transistor 90 is connected to the terminals 16 and 17 via a diode 76 and a resistor 77 or ground 5 are connected. Because the collector-emitter circuits of the transistors 80 and 90 with the positive and negative terminals of the DC power source 8 in the correct manner for one NPN transistor are connected, these ratios are when switch 56 is closed, which is a usual Ignition switch can be before. When the switch 56 is closed, a current is passed through the base-emitter circuit of the transistor 80 closed, which is from the positive terminal of the direct current source 8 via the switch 56, the conductor 48, the resistor 68, the base-emitter circuit of the transistor 80 via Ground 5 to the negative pole of the direct current source 8 is running. The transistor 80 is therefore normally conductive and closes the excitation circuit for the primary winding 37 of the converter 36.

A charging circuit for capacitor 69 is also closed and runs from the positive terminal the direct current source 8 via the switch 56, the conductor 48, the resistor 67, the capacitor 69, the base-emitter circuit of transistor 80 and ground 5 to the negative terminal of the DC power source 8. The capacitor 69 is thus charged, with the one connected to the connection point 75 Has positive polarity.

Since the base electrode 91 of the transistor 90 when the breaker contacts 10 and 10 a is connected to ground 5, the transistor 90 is non-conductive when the interrupter contacts are closed.

Each time the breaker contacts 10 and 10a open, a current flows through the base-emitter circuit of the transistor 90 from the positive terminal of the DC power source 8 via the switch 56, the Conductor 48, resistor 58, diode 76, resistor 77, the base-emitter circuit of the transistor 90 via ground 5 to the negative terminal of the DC power source 8. In this way, the Ignition signals introduced via terminals 16 and 17.

As a result, the transistor 90 is conductive in its collector-emitter circuit and connects the Capacitor 69 of opposite polarity across the base-emitter circuit of transistor 80 and forms by erasing the transistor 80, a discharge circuit for the capacitor 69, which is via the Connection point 95, the collector-emitter circuit of the transistor 90, ground 5, direct current source 8, switch 56, conductor 48 and resistor 68 to the other side of the capacitor 69 runs. This circle is the Time circuit which the transistor 80 after a certain time, which from the ÄC time constant of the Capacitor 69 and resistor 68 is given, the return to the original switching position permitted, in which it is conductive in the collector-emitter circuit.

When the transistor 80 is non-conductive, the excitation “ki ei” of the primary winding 37 of the converter 36 is applied interrupted so that the excitation current ends Drs collapsing magnetic field of the primary winding 37 generates a voltage in the primary winding 37 which is positive on its side 46 with respect to ground 5 This positive signal appears across capacitor 44 and diode 45 between the output terminal 28 and mass 5.

The collapsing magnetic field of the primary winding 37 also induces a voltage with positive polarity on its side 59 in the secondary winding 38. This voltage is blocked from the output terminal 28 by a diode 55 and is diverted via a resistor 84.
If the capacitor 69 is discharged after a time determined by the /? C time constant, the voltage having the opposite polarity is removed from the base-emitter circuit of the transistor 80, so that the transistor 80 becomes conductive again in the collector-emitter circuit

ίο will and the excitation current for the primary winding 37 of the converter 36 switches on again. The resulting increasing current through the primary winding 37 builds up a corresponding magnetic field which induces a voltage in the secondary winding 38, which is positive with respect to ground 5 on the side 58 of the secondary winding 38. This positive signal will passed through the capacitor 54 and the diode 55 and appears between the output terminal 28 and Mass 5.

The next time the breaker contacts 10 and 10a open, what has just been described are repeated Operations so that two switching pulses of the same polarity between the output terminal 28 and Mass 5 for each incoming ignition signal! on

he reason for the opening of the breaker contacts 10 and 10 α arise.

In the ignition system according to Fig. 2, this part is The ignition system is slightly modified by adding another pnp transistor 100 with a base electrode 101, a collector electrode 102 and an emitter electrode 103 is provided.

As with the system of FIG. 1, the transistor is 80 normally conductive. If there is no ignition signal at terminals 16 and 17, so no emitter-base current flows to transistor 100, so that it is normally non-conductive. at Non-conductive transistor 100, the base-emitter circuit of the transistor 90 is interrupted, so that so normally transistor 90 is also non-conductive.

The sensing coil 14 is wound on the pole piece 12 that the cams of the armature 15 to the Run the pole tips close and then an ignition signal of positive polarity at the connection terminal 16 deliver.

When an ignition signal occurs at terminals 16 and 17, an emitter base current flows through transistor 100 from terminal 16 through resistor 85, the emitter base circuit of transistor 100, a resistor 86 to terminal 17 on the other side of the sense coil 14. The transistor 100 is thereby conductive in the emitter-collector circuit, so that a circle of the positive terminal of the DC power source 8 over

the switch 56, the conductor 48, the resistor 87, a conductor 88, the emitter-collector circuit of the Transistor 100, resistor 94, resistor 95. Ma «aa» 5 to the negative terminal of the direct current source 8 is closed. The conductive transistor 100 closes a circuit for the base-emitter current through transistor 90 to switch transistor 90 so that it is in the collector-emitter circuit Current leads. With transistor 90 conducting, the sequence of processes is the same as for the ignition system.

measure F i g. 1 in the rest of the circle, se daii two Switching signals of the same polarity between output terminal 28 and ground 5 arise.

By choosing the resistance values of the resistors

Stands 67 and 68 and the capacitance of the capacitor 69 can be the period between two switching signals can be made dependent on the engine speed. The resistance value of the Resistor 68 and the capacitance of capacitor 69 determine the length of time in which the transistor 80 remains non-conductive and thus the time span between the two switchover signals. The 'resistance value of resistor 67 and the capacitance of capacitor 69 determine the length of time which is required to charge the capacitor 69. These values can be chosen so that a Time constant of sufficient size is achieved at the idling speed of the internal combustion engine allows the capacitor 69 to be fully charged, but is insufficient to fully charge it of the capacitor 69 to allow at high engine speeds. With a lower charge of the capacitor 69, the discharge time of the capacitor 69 is shorter, so that the switching process occurs earlier at transistor 80, so that with increasing engine speed the Time span between the two switchover signals becomes smaller. The one just described Circular switching signals that appear between output terminal 28 and ground 5 are on the output terminal 28 positive with respect to ground 5 and become the base-emitter circuit of the switching transistor 50 fed in the correct polarity, so that a base-emitter current flows and therefore the switching transistor 50 is conductive in its collector-emitter circuit. The switching transistor 50 is therefore at conductive for each switchover signal.

The conductive transistor 50 completes a circuit from the positive terminal of the direct current source 8 its collector-emitter circuit and a series resistor 96. The current through the resistor 96 supplies a switching signal which is positive with respect to ground 5 at a connection point 97. This switching signal is fed to the base-emitter circuit of the switching transistor 40 with the correct polarity, so that a base-emitter current flows through which the switching transistor 40 in its collector-emitter circuit becomes conductive.

The conductive switching transistor 40 connects the positive Connection point 98 of the bias circuit, which consists of the series resistors 34 and 35 exists, with ground 5 via the control resistors 30 and 31. The voltage between the connection point 98 and ground 5 here have a size that corresponds to the voltage drop in the control resistors 30 and 31 and the collector-emitter circuit of the switching transistor 40 corresponds. The control resistors 30 and 31 are therefore selected so that when the switching transistor 40 initially becomes conductive, a complete one Voltage drop in the control resistors 30 and 31 and the collector-emitter circuit of the Switching transistor 40 occurs and is of insufficient size to carry the control current through the base-emitter circuit of the control transistor 50, so that this and the transistor 60 are cleared will.

With control transistors 60 and 70 cleared, when switching transistor 40 initially becomes conductive a control circuit is closed that has a base-emitter current through the switchover transistor 50 through series resistors 105, 106, a diode 107, the base-emitter circuit of the switching transistor 50 and a resistor 96 flows to the switching transistor 50 and thus to keep the switching transistor 40 conductive. The conductive switching transistor 40 closes the excitation circuit for the primary winding 25 of the converter 24, which is connected to the control resistors 30 and 31 is connected in series with the positive terminal of the DC power source 8.

When the excitation circuit for the primary winding 25 of the converter 24 is closed, the excitation current increases and forms a correspondingly increasing magnetic field, which in the secondary winding 26 a Voltage induced, which is positive at a connection terminal 108 with respect to a connection terminal 109 is. Furthermore, a voltage is induced in a switching winding 112, which is applied to a connecting terminal 110 has positive polarity with respect to a terminal 111. A blocking diode 114 prevents a current through the secondary winding 26, so that the voltage induced in this has no effect

remain. The purpose of the voltage induced in switch winding 112 will be explained later will.

The excitation current increases through the primary winding 25 of the converter 24 and through the control resistors 30 and 31, the voltage at connection point 98 increases. This positive signal becomes the Base-emitter circuit of the control transistor 70 via the resistors 34 and 35 connected in series and is connected to ground 5, so that the polarity is correct to allow a base-emitter current to flow through the Allow control transistor 70. If the voltage drop in the control resistors reaches 31 and 30 a predetermined value, this signal causes a base-emitter current in transistor 70, which accordingly in the collector-emitter circuit becomes conductive and in turn the base-emitter circuit of the control transistor 70 feeds, so that this becomes conductive in the collector-emitter circuit.

The conductive control transistors 60 and 70 divert the base current from the switching transistor 50, see above that this is deleted. If the switching transistor 50 is not conducting, the switching signal disappears at the resistor 96 and thus also in the base-emitter circuit of the switching transistor 40, so that the switching trans

Φ5 sistor 40 is deleted and the excitation circuit for the Primary winding 25 of converter 24 is interrupted.

The collapsing field of the primary winding 25 induces the charging voltage for the Ignition capacitor 18 in secondary winding 26.

which at terminal 109 has positive polarity with respect to terminal 108. Fernei a voltage is induced in the switching winding 112, the polarity at connection terminal 111 has positive polarity with respect to connection terminal 110. By the ignition voltage is charged to the ignition capacitor Ii through a circuit drawn from the terminal 109 via the diode 114, the ignition capacitor 18, the primary winding 20 of the ignition coil 19 to this parallel resistors 115 and diode 116, ground 5 and a resistor 150, dei to the base-emitter circuit of a transistor 160 is parallel to the other terminal 108 of the secondary winding 26 leads. The ignition capacitor 18 is charged, the one having a connection point 12C

Connected pad positive polarity compared to the other pad has a diode 122 prevents one Current through the switching winding 112, so that the voltage induced by this has no effect

309512/24 /

9 10

The charge of the ignition capacitor 18 is decorated over. This is bad about a not shown Anode-cathode circuit of the controlled silicon ignition distributor, the spark plugs of the internal combustion rectifier 22 via a conductor 124 and through the machine.

Primary winding 20 of ignition coil 19 to ground 5 At high engine speeds,

derived. Since the polarity of the charge at that with 5 NEN the two supplied by the converter 36

the connection point 120 connected coating of the switching signals so closely that the

Ignition capacitor 18 is positive, the voltage at the second signal occurs before ignition capacitor 18

the anode of the silicon controlled rectifier 22 is fully charged. In this case it would

positive and negative at the cathode. second signal the controlled silicon rectifier 22

The silicon controlled rectifier 22 is an io to switch to the conductive state while turning off Semiconductor device with a control electrode, also the ignition capacitor 18 charges. This would mean grid electrode called, and both of them carried current, that the charging and discharging circuit of the ignition end Electrodes in the form of the anode and cathode. capacitor 18 would be closed at the same time. Around It is designed so that it is normally one to prevent this undesirable condition Locks electricity in both directions. With in forward 15 signal suppression transistor 160 with a base direction polarized anode and cathode, ie anode electrode 161, a collector electrode 162 and one positive and cathode negative, the controlled emitter electrode 163 can be provided. The collector elec silicon rectifiers The conductive state is traded 162 with the connection point between which the grid electrode is switched by a control diode 107 and the base electrode of the switchover signal of a polarity connected to the transistor 50 which is the emitter electrode 163 The instantaneous voltage at the cathode is positive with the connection terminal 108 of the secondary winding and is large enough to be connected to one of the grid 26, and the base electrode 161 is connected to Electrode to the cathode flowing control current to ground 5 via a resistor 165 connected. At the works. In the conductive state, the controlled Si charging of the ignition capacitor 18 flows through the silicon rectifier Conduct current in one direction, each current through resistor 150 from ground 5 in but blocked in the opposite direction, direction to terminal 108 of the seconds. In the conductive state, the controlled silicon winding 26 acts. The through the charging current in the converter like a common diode. After resistor 150 causes a voltage drop developed after switching to the conductive state, the signal at the emitter electrode 163 of the signal suppressing grid electrode the rectifier, however, no longer affects a voltage that is somewhat less, so that this in the conductive state is ger positive than the voltage on the base electrode remains until either the anode-cathode circle is un- 161. A base-emitter current therefore flows in the broken grid or the polarity of the in the analog suppression transistor 160 when the ignition-cathode circuit prevailing tension changes. capacitor 18 is charged. Occurs at this time Of these two options, the change to 35 is a second switchover pulse, so this is over Polarity in the anode-cathode circuit probably the collector-emitter circuit of the signal suppressor more advantageous. kung transistor 160, which is connected to the switching

At the next switching signal, which is short-circuited at the off transistor 50 so that the second output terminal 28 and ground 5 appear, the switching pulse at the switching transistor 50 repeats the processes described ineffective. The next time it is 40 sampled and therefore the switching transistor 40 in the start of conduction of the conduction of the switching transistor 40, which holds the state. Since the connecting terminal 110 of the increasing magnetic field of the primary winding 25 switching winding 112 is positive compared to the connection as a result of the increasing excitation current at the terminal 111, there is a connection between the connection of a voltage in the switching winding 112 terminal 110 and the collector electrode of the signal with positive polarity at the Terminal 110 45 suppressing transistor 160 lying resistance opposite terminal 111. This inductive 168 an additional positive voltage at the collated voltage causes a current through a lektorelectrode 162 of the signal suppression transistor circuit, which starts from terminal 110 via the stors 160, see above that an additional security for diode 122, the Widei stand 125, the capacitor 126 and resistor 160 lying in series with this parallel conducting state of the signal suppression transistor is given, as long as the ignition capacitor stood 127 via ground 5 to the other Terminal 18 is charged. When the secondary winding is open, terminal 111 runs. The charging current for a capacitor of the ignition coil causes the inductance-reactance circuit capacitor 126 to flow through a resistor 127, to which a voltage signal occurs from the primary winding 20 of the ignition coil 19 and the positive polarity of the ignition capacitor 18 has a ringing effect, which did at a connection point 130 with respect to ground 5 55 has the ignition capacitor 18 in the opposite direction. This signal will charge the grid cathode circuit. The ignition capacitor 18 is then discharged to the controlled silicon rectifier 22 with the correct polarity being fed in the reverse direction through the primary winding, so that a grid current flows. 20. This causes the controlled silicon rectification to erase the charge of the ignition capacitor 18 to the ter 22 and charges the ignition capacitor 18 in the anode-cathode circuit of the controlled silicon 60 forward direction via the diode 132, which opposes the rectifier 22 with the correct polarity at the anode If high voltage is fed to the ignition capacitor and cathode, it becomes conductive in the anode gate 18 to the anode-cathode circuit of the control cathode circuit and connects the ignition capacitor silicon rectifier 22 because the capacitor 18 connects to the primary winding 20 of the ignition-ignition capacitor Forward direction τηχ cutiaden coil 19. The charge of the ignition capacitor 18 searches for 65, while the controlled silicon rectifier charges quickly through the primary winding 20 22 is non-conductive, the voltage on the anode rises and generates a magnetic field in this that quickly creates a high cathode circuit at. A capacitor 134 and ignition voltage in the secondary winding 21 induce a diode 135 and a parallel to this

Resistor 136 acts as a filter which reduces the voltage build-up, as a result of which the controlled silicon rectifier 22 is prevented from switching over to the conductive state in the anode-cathode circuit as a result of the strong dE / dt applied to it.

The diode 116 is a free-running diode which is parallel to the primary winding 20 in order to dampen oscillations in this during the flashover at a spark gap. The resistor 138 is a bleeder resistor through which the ignition capacitor 18 is discharged when the switch 56 is open. The thermal

stör 140 causes a temperature equalization. The capacitor 142 is a filter capacitor, and the Zener diode 144 protects the switching transistor 40 if the ignition coil 19 should be separated from the circuit of the ignition system. In the exemplary embodiment, special types of transistors, electrical polarities and components are specified. Modified types of transistors, corresponding polarities and modified components can be used within the framework of the invention, provided that only the function is the same.

1 sheet of drawings

Claims (3)

Patent claims: 1. Ignition circuit for an ignition system for internal combustion engines, in which two consecutive discharges with a delay are triggered by an ignition signal generator via at least two control circuits, characterized by a converter C * 6) with a primary winding (37) and a secondary winding (38), which are connected with opposite polarity to terminals (2S _x S) of the circuit, a transistor (80) with a control electrode (81) and two current-carrying electrodes (82, 83), the current-carrying electrodes being in series with the primary winding on a direct current source , and by a capacitor (69) and two resistors (67, 68), wherein an RC charging circuit for the capacitor at least the capacitor, the one resistor (67), the control electrode (81) and one of the current-carrying electrodes (82, 83) of the transistor (80) in series between the direct current source (8) and a second switching device (90), and the second switching device at each em at the terminals (16, 17) occurring ignition signal the capacitor (69) with opposite polarity with its control electrode (91) and one of its two current-carrying electrodes (92, 93) connects to a discharge circuit for the capacitor (69) via the second Resistance (68) to close. 2. ignition circuit according to claim 1, characterized in that the second switching device a second transistor (90) having a base electrode (91), an emitter electrode (93) and a The collector electrode (92) is connected to the base-emitter circuit with the terminals (16, 17) of the signal generator is connected and its collector electrode via the first resistor (67) is connected to the direct current source (8) and to the one plate of the capacitor (69) whose other coating via the second resistor (68) with the direct current source (8) and with the Control electrode (81) of the first transistor (80) is connected. 3. ignition circuit according to claim 1 or 2, characterized by one on the charging current of the Ignition capacitor (18) at high engine speed responsive signal suppression circuit (160), the one path lying parallel to the transducer circle for the second path for each Ignition signal supplied switching signals forms.