DE1956813A1 - Ignition system with ignition capacitor - Google Patents

Description

General Motors Corporation, Detroit, Mich., Y ₀ St.A "

Ignition system with ignition capacitor

The invention relates to an ignition system with ignition capacitor with one of the speed of an internal combustion engine dependent. Ignition signal generator, a converter circuit which responds to the ignition signals and which controls the charging voltage for the ignition capacitor, which is in an output circuit that provides the charging circuit for the ignition capacitor, the Contains the primary winding of the ignition coil and an ignition capacitor switch that connects them *

The invention deals with the difficulty that is characteristic of ignition systems with ignition capacitors, namely the period in which the ignition spark in the spark gap is maintained, is relatively short. At certain speeds and outputs of the internal combustion engine

009820/1389

1156813

it is possible that a combustible mixture in the B _e of the spark plug electrodes during the flashover of the spark gap is not present rich. This is due to insufficient turbulence in the intake box and the intake ducts of the internal combustion engine, which prevents an intimate mixture between fuel and air. Particularly at low powers, this leads to an uneven running _{T of} the internal combustion engine due to misfire.

An ignition system is known from US Pat. No. 3,394,689, but which does not have an ignition capacitor works, but allows multiple ignition in the combustion chamber at each ignition point. The primary winding of the The ignition coil forms part of a resonance circuit in which the vibrations necessary to achieve a multiple Ignition. In contrast to this, in the case of the ignition system with an ignition capacitor according to the invention, each working stroke of the cylinder, ignition occurs through two temporally separated overlaps, which are triggered by clear switching signals are controlled, so that the resonance circuit required in the known ignition system can be dispensed with.

The solution to this problem is, according to the invention, that a circle is provided, which with each Ignition signal supplies two switching signals of the same polarity and the circuit is a DC power source, terminals for

ÖQ982Q / 1369

195681

the connection of the signal transmitter, a converter with a Primary winding and a secondary winding with opposite polarity at the output terminals of the circuit are connected, a transistor with a control electrode and two current-carrying electrodes, the current-carrying devu Electrode .-, in series with the primary winding on the DC power source liegfei, and contains a capacitor and two resistors, with an RC charging circuit for the capacitor at least the capacitor, the resistor, the control electrode and one of the current-carrying electrodes of the transistor in series between the direct current source and a second switching device, and the second switching device with each ignition signal appearing at the connection terminals the capacitor with opposite polarity its control electrode and one of its two current-carrying electrodes connects to a discharge circuit for the capacitor to close over the second resistance.

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 connected to the base-emitter circuit with the connection terminals of the signal generator and its collector electrode via the first resistor to the direct current source and to one plate of the capacitor whose other plate is connected via the second resistor

- 4 ÖÖ 9 820 / Ϊ3Ϊ9 '"" "'

is connected to the direct current source and to the control electrode of the first transistor. It is also identified the invention by one on the charging current of the ignition capacitor at high engine speed responsive signal suppression circuit, the one parallel to the converter circuit forms lying path for the second of the switching signals supplied with each ignition signal.

With this design of the ignition system, two ignition is achieved with each working stroke. If a combustible mixture is not present at the time of the first flashover at the spark gap, there is a second possibility of ignition through the second flashover at the spark gap, which occurs about twenty crankshaft degrees later. At the moment of the second arcing at the spark gap is the possibility of the presence of a combustible premix G _e considerably large due to the already onset of densification and the turbulence of the mixture in the combustion chamber. The invention significantly expands the possibility of using ignition systems with ignition capacitors, which is advantageous per se, since their use is made possible even under difficult operating conditions.

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

009 8 20 / 13β9

Fig. 1 is a circuit "image of an ignition system

of the invention using a common ignition distributor with breaker contacts and

Pig. 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.

In general, both ignition systems with an ignition capacitor contain an ignition signal generator that reacts to the speed of the Internal combustion engine delivers matched ignition signals, one on-: each ignition signal responsive circuit to two toggle signals to form the same polarity, a converter circuit, which responds to any Umsehaltsignal, to the charging voltage for the Form ignition capacitor, and an output circuit in which the discharge of the ignition capacitor through the primary winding the ignition coil takes place with every output signal from the converter circuit. The individual circuits of the ignition system are controlled by a usual storage battery 8 supplied.

In the ignition system according to Mg. 1, the signal transmitter is a common one due to two interrupter contacts 10 and 10a Ignition interrupter formed, which are opened and closed depending on the speed of the internal combustion engine, including

820/1319

a rotating cam is used in a known manner. In the. Pig ignition system. 2, an electromagnetic distributor is used as a signal transmitter, which is formed from a pole piece 12 for forming a field and a sensing coil 14 which is wound around an armature 15 provided with cams. The armature 15 is driven as a function of the speed of the internal combustion engine and supplies ignition signals in a manner known per se. The current-dependent converter circuit contains a converter 24 with a primary winding 25 and a secondary winding 26. Control resistors 30 and 31 connected in parallel to one another are connected to the primary winding 25 in series, as well as a normally non-conductive npn switching transistor 40 with a control electrode and two current-carrying electrodes. This circuit is connected to the DC source 8. Further, a switching circuit for forming a switching signal in response to each trigger signal ⁵ is provided, which includes a normally nonconductive npn switching transistor 50 with associated circuit. A control circuit, which responds to the pressure drop in the control resistors 30 and 31, for switching off the switching circuit when a voltage drop of a certain value is reached in the control resistors consists of two normally conductive npn transistors 60 and 70, which are arranged in a Darlington circuit and the associated circuit. Another circle that made up

in series resistors 33, 34 and 35 is used the supply line of the incoming at the control resistors 30 and 31 Voltage drop to the control circuit.

The output circuit contains an ignition capacitor 18 with an associated charging circuit, the primary winding 20 one conventional ignition coil 19, which has a secondary winding 21 and an ignition capacitor switch 22 in the form of a controlled silicon rectifier, which connects the ignition capacitor 18 to the primary winding 20 of the ignition coil.

The circuit for generating two switching signals of the same polarity depending on each ignition signal consists of an input circuit, to which the Zfitidsignale are fed via the connection terminals 16 and 17, and an output circuit, which has an output terminal 28 and a ground terminal 5. The circuit also contains a converter 36 with a primary winding 37 located in the input circuit and a secondary winding 38 located in the output circuit, which are connected to the output terminals of the circuit with opposite polarity. An excitation circuit for the primary winding 27 of the converter 36 contains a first controllable switching device for connecting or disconnecting the positive side of the direct current source. F _e rn a timing circuit is provided which connects the input circuit and the controllable switching means such that

009820/1369

the switching device reverses the polarities switched on the basis of a supplied ignition signal after a certain time .

The primary winding 57 of the converter 56 is with their side 46 connected to the output terminal 28 via a resistor 44 and a diode 45 and with their side A conductor 48, the movable contact arm 57 of a bracket 56 and the direct current source 8 are connected to ground 5. The secondary winding 58 of the converter 56 is connected to the output terminal 28 connected from its side 58 via a capacitor and a diode 55 and with its side 59 via a Conductor 64 is connected to ground 5, so that it is connected with the polarity opposite to that of the primary winding 57. The positive side of the primary winding 57 is therefore connected to the output terminal 28 when the excitation circuit is interrupted, while the other side is at Maese 5, while the positive polarity side of the secondary winding 58 is at Switching on the excitation circuit for the primary winding 57 is connected to the output terminal 28, while its other Side is on ground 5.

The timing circuit between the terminals 16 and 17 and the first controllable switching device is designed so that it switches the transistor 80 back to the initial state after a certain time has elapsed, as will be explained later. The time switch

ÖÖ98207 1369

circuit contains resistors 67 and 68 and a capacitor 69 and a second controllable switching device. This can be designed as an npn transistor 90, which responds to every ignition signal, that appears at the terminals 16 and 17, responds to the capacitor 69 with opposite To connect polarity via the base-emitter circuit of the transistor 80 and thus a discharge circuit for the capacitor 69 to close.

The excitation circuit for the primary winding 37 of the converter 36 is, as mentioned, an npn transistor 80 with a base electrode 81, a collector electrode 82 and an emitter electrode 83. The primary winding 37 and the current-carrying collector-emitter circuit of the transistor 80 are connected in series with the direct current source 8 when the switch 56 is closed, the connection via a resistor 74, the conductor 48 and the switch 56 to ground 5 takes place.

There is a charging circuit for the capacitor 69 from the resistor 67, the capacitor 69 and the base-emitter circuit of transistor 80 and lies between positive conductor 48 and ground 5.

The collector-emitter circuit of the transistor 90 is connected to a connection point 75 between the capacitor 69 and the resistor 67 and the emitter electrode 83 of the transistor 80 connected to Hasse 5.

- 10 -

309820/1363

Resistor 68 is connected to the base electrode of transistor 80 and the emitter electrode 93 of the transistor 90 and is connected to ground 5 via the positive conductor 48, the switch 56 and the DC power source 8.

The base-emitter circuit of the transistor 90 is connected to the connection terminals 16 and 17 via a diode 76 and a resistor 77 or ground 5 connected, since the collector-emitter circuits of transistors 80 and 90 with the positive and negative terminals of the DC power source 8 are properly connected for an npn transistor, they are Conditions when switch 56 is closed, which can be a conventional ignition switch. When the switch is closed becomes a current through the base-emitter circuit of the transistor closed, from the positive terminal of the DC power source 8 via the switch 56, the conductor 48, the resistor 68, the The base-emitter circuit of the transistor 80 runs via ground 5 to the negative pole of the direct current source 8. 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 of the direct current source 8 via switch 56, conductor 48, the resistor 67, the capacitor 69, the basls-emitter circuit of the transistor 80 and ground 5 to the negative terminal of the direct current source. The capacitor 69 is thus charged, the with the

Connection point 75 connected plate has positive polarity.

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

Each time the breaker contacts 10 and 10a, a current flows through the base-emitter circuit of the transistor 90 from the positive terminal of the direct current source 8 via the switch 56, the conductor 48, the resistor 58, the mode 76, the 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 are over the terminals 16 and 17 introduced.

This renders transistor 90 in its collector-emitter circuit conductive and connects the capacitor 69 with opposite polarity via the base-emitter circuit of the Transistor 80 and forms, with the erasure of transistor 80, a discharge circuit for capacitor 69, which is via the Connection point 95, the collector-emitter circuit of the transistor 90, Hasse 5, DC power source 8, 'switch 56, conductor 4-8 and Resistor 68 runs to the other side of capacitor 69 · This circuit is the timing circuit that drives transistor 80 after a certain time, which is derived from the RC time constant of the Capacitor 69 and resistor 68 is given, which allows a return to the original switching position, in which it is conductive in the collector-emitter circuit.

- 12 -

Ö09820 / 1369

When the transistor 80 is non-conductive, the excitation circuit of the primary winding 37 of the converter 36 is interrupted, so that the excitation current ends. The collapsing magnetic field of the primary winding 37 generates in the primary winding;

f 37 a voltage which is positive on its side 46 with respect to ground 5. This positive signal appears across the capacitor 44 and the diode 45 between the output terminal 28 and Mass 5.

The collapsing magnetic field of the primary winding 37 also induces a in the secondary winding 38 Voltage with positive polarity on its side 59. This voltage is from the output terminal 28 through a diode55 blocked and is diverted via a resistor 84.

If the capacitor 69 is discharged after a time determined by the RC time constant, the opposite occurs Voltage exhibiting polarity at the base emitter circle of the transistor 80 removed, so that this becomes conductive again in the collector-emitter circuit and the excitation current for the Primary winding 37 of 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 that is applied to the side 58 of the Secondary winding 38 is positive with respect to ground 5. This positive signal is across the capacitor 54 and the diode and appears between output terminal 28 and ground 5.

- 13-

00 9 820/1 36'9

The next time the breaker contacts open 10 and 10a repeat the processes just described, so that two switching pulses of the same polarity between the output terminal 28 and ground 5 for each incoming ignition signal arise due to the opening of the breaker contacts 10 and 10a.

In the ignition system according to Pig «2, this part of the ignition system is slightly modified by adding a further pnp transistor 100 with a base electrode 101, a collector electrode 102 and an emitter electrode is provided.

As with the investment according to Pig. 1 is the

Transistor 80 normally conductive. Located on the connection terminals 16 and 17 there is no ignition signal, so no emitter base current flows to transistor 100, so that this normally occurs is non-conductive. When transistor 100 is non-conductive, the base-emitter circuit of transistor 90 is interrupted, so that the transistor 90 is normally also non-conductive.

The sensing coil 14 is wound onto the pole piece 12 in such a way that the cams of the armature 15 are on the pole tips close vs and then an ignition signal of positive polarity

- 14 -

9820/1360

at the connection terminal 16.

When an ignition signal occurs at the connection terminals 16 and 17, an emitter base current flows through the Transistor 100 from the connection terminal 16 via a resistor 85, the emitter-base circuit of the transistor 100, a Resistor 86 to the connection terminal 17 on the other side of the sensing coil 14. The transistor 100 is thereby in the Emitter-collector circuit conductive, so that a circuit from the positive terminal of the green current source 8 via the switch 56,

j the conductor 48, the resistor 87, a conductor 88, the emitter-j

Collector circuit of the transistor 100, a resistor 94, ί

a resistor 95, ground 5 to the negative terminal of equal j

power source 8 is closed. The conductive transistor 100 closes a circuit for the base-emitter current through the Transistor 90 to toggle transistor 90 so that it conducts current in the collector emitter circuit. At senior Transistor 90 results in the sequence of the processes as in the ignition system according to FIG. 1 in the remaining part of the circle, see above that two switching signals of the same polarity between the Output terminal 28 and ground 5 arise.

By choosing the resistance values of the resistors 67 and 68 and the capacitance of the capacitor 69, the period between two switchover signals depends on the South engine speed can be made. The resistance value

- 15 -

009820/1369

of the resistor 68 and the capacitance of the capacitor 69 determine the length of time in which the transistor 80 remains non-conductive and thus the time between the two toggle signals. The resistance value of the resistor 67 and the capacitance of the capacitor 69 ″ determine the length the time it takes for the capacitor 69 to charge. These values can be chosen so that a time constant Sufficient size is achieved, the hot idling speed of the internal combustion engine complete charging of the capacitor 69 allows, but is insufficient to fully charge the capacitor 69 hot To allow internal combustion engine speeds. If the charge of the capacitor 69 is lower, the discharge time is also lower of the capacitor 69 is lower, so that the switching process at the transistor 80 occurs earlier, so that with increasing Internal combustion engine speed the time between the two switching signals is smaller. The switching signals formed by the circle just described, between the Output terminal 28 and ground 5 appear are at the output terminal 28 positive to ground 5 and are the base-emitter circuit of the switching transistor 50 in the correct Polarity fed, so that a base-emitter current flows and therefore the switching transistor 50 in its collector-emitter circuit is conductive. The switching transistor 50 is therefore conductive with every changeover signal.

- 16 -

009820 / 1.369

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

The conductive switching transistor 40 connects

the positive terminal 98 of the bias circuit, the consists of the series resistors 34 and 35, with ground 5 via the control resistors 30 and 31. The voltage between the connection point 98 and ground 5 has here 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 such that when the switching transistor 40 initially becomes conductive, there is a complete voltage drop occurs in the control resistors 30 and 31 and the collector-emitter circuit of the switching transistor 40 and an insufficient Has large in order to maintain the control current through the base-emitter circuit of the control transistor 50, so that this and the transistor 60 are cleared.

- 17 -

Ö098207 1369

With control transistors 60 and 70 cleared

"when switching transistor 40 initially becomes conductive a control circuit is closed, the base-emitter current through the switching transistor 50 through series resistors 105,106, a diode 107 »the base-emitter circuit of the switching transistor 50 and a resistor 96 flows around to keep the switching transistor 50 and thus the switching transistor conductive. The conductive switching transistor 40 closes the excitation circuit for the primary winding 25 of the converter 24 » j those lying in series with the control resistors 30 and 31

the positive terminal of the direct current source 8 is connected _o • When the excitation circuit for the primary

winding 25 of the converter 24 increases the excitation current and forms a correspondingly increasing magnetic field, which induces a voltage in the secondary winding 26 which is positive at a connection terminal 108 compared to a connection terminal 109 is. Furthermore, a voltage is indicated in a switching winding 112, which is connected to a connection terminal 110 has positive polarity with respect to a connection terminal 111. A blocking diode 114 prevents current through the secondary winding 26, so that the voltage induced in this has no effect. The purpose of the induced in the switching winding 112 Voltage will be explained later,

- 18 -

6Ό9820 / 1369

The exciting current increases through the primary winding 25 of the Umwandiers 24 and through the control resistors 30 and 31, so the voltage at the connection point 98. This positive signal is supplied to the base-emitter circuit of control transistor 70 and supplied via the ihe in R _e lying resistors 34 and is at ground 5 so that the polarity is correct to allow a base-emitter current through the control transistor 70. If the voltage drop in the control resistors 31 and 30 reaches a predetermined value, this signal causes a base-emitter current in the transistor 70, which consequently becomes conductive in the collector-emitter circuit and in turn feeds the base-emitter circuit of the control transistor 70, so that it is in the collector- Emitter circuit becomes conductive.

The conductive control transistors 60 and 70 divert the base current from the switching transistor 50, so that this is deleted. When the switchover transistor 50 is non-conductive, the switchover signal at the resistor 96 and thus disappears also in the base-emitter circuit of the switching transistor 40, so that the switching transistor 40 is deleted and the excitation circuit for the primary winding 25 of the converter 24 is interrupted.

The collapsing field of the primary winding 25 induces the charging voltage for the ignition capacitor 18 in of the secondary winding 26, which is connected to the connection terminal 109

- 19 -

Austria 0-9820 / 1 369

has positive polarity with respect to the connection terminal 108. Furthermore, a voltage is induced in the switching winding 112, the Jan of the terminal 111 has positive polarity opposite the terminal 110 has. The ignition capacitor 18 is charged by the ignition voltage through a circuit that is controlled by the connection terminal 109 via the diode 114, the ignition capacitor 18, the primary winding 20 of the ignition coil 19, which leads to j

this parallel resistors 115 and diode 116, ground 5 and a resistor 150, which is the base Emmtterkreis of a transistor 160 is parallel, leads to the other connection terminal 108 of the secondary winding 26. The ignition capacitor 18 is charged with the plate connected to a connection point 120 having positive polarity with respect to the has another plate. A diode 122 prevents a current through the switching winding 112, so that the induced in this Tension has no effect.

The charge of the ignition capacitor 18 is via the anode-cathode circuit of the controlled silicon rectifier 22 through a conductor 124 and through the primary winding 20 of the ignition coil 19 is derived to ground 5. Because the polarity of the charge at that connected to the connection point 120 Plate of the ignition capacitor 18 is positive, the voltage at the anode of the silicon controlled rectifier 22 is positive and negative at the cathode.

- 10- & Ü 9 82 0/13 6 9 ~~ —— -

1958813

■ - 20 -

The controlled silicon rectifier 22 is a semiconductor device with a control electrode, also called a grid electrode, and the two current-carrying electrodes in the form of the anode and cathode. It is designed in such a way that it normally blocks a current in both directions i. Positively poled in the forward direction of the anode and cathode, so the anode and cathode is negative, the controlled \ silicon controlled rectifier can be switched into the conductive state in which the grid electrode is fed to a control signal of a j polarity, that is positive to the current j voltage to the cathode and is sufficiently large to cause a control current flowing from the grid electrode to the cathode. In the conductive state, the stepped silicon rectifier will conduct current in one direction, but remain blocked in the opposite direction. In the conductive state, the controlled silicon rectifier acts like a conventional diode. After switching to the conductive state, the grid electrode can no longer influence the rectifier, so that it remains in the conductive state until either the anode-cathode circuit is interrupted or the polarity of the voltage in the anode-cathode circuit changes. Of these two possibilities, changing the polarity in the anode-cathode circuit is probably the more advantageous.

- 21 -

009820/1369

With the next one. Umsehaltsignal that at the Output terminal 28 and ground 5 appear, the processes described are repeated. The next time you start running the Switching transistor 40 causes the increasing magnetic field of the primary winding 25 as a result of the increasing excitation current the induction of a voltage in the switching winding 112 with positive polarity at the connecting terminal 110 the terminal 111. This induced voltage causes a current through a circuit by the terminal 110 through the diode 122, the resistor 125, the capacitor 126 and the resistor, which are connected in parallel with them in series 127 runs via ground 5 to the other connection terminal 111. The charging current for a capacitor 126 flows through a Resistor 127, at which a voltage signal occurs, the positive polarity at a connection point 150 with respect to ground This signal is sent to the grid-cathode circuit of the silicon controlled rectifier 22 with correct polarity so that a grid current flows. If the charge of the ignition capacitor 18 is the anode-cathode circuit of the controlled Silicon rectifier 22 supplied with the correct polarity at the anode and cathode, this is in the anode-cathode circuit conductive and connects the ignition capacitor 18 to the primary winding 20 of the ignition coil 19. The charge of the ignition capacitor 18 therefore quickly discharges through the primary winding

- 22 -

Ö09820 / 1369

and generates a magnetic field in it, which induces a high ignition voltage in the secondary winding 21. This will via a conventional ignition distributor, not shown

Spark plugs supplied to the internal combustion engine. At high engine speeds, '

the two switching signals j supplied by the converter 36 so close together that the second signal occurs. j

before the ignition capacitor 18 is fully charged. j In this case the second signal would be the controlled | Switch the silicon rectifier 22 into the conductive state while the ignition capacitor 18 is charging. This would be |

mean that the charging and discharging circuit of the ignition capacitor 18 would be closed at the same time. To this undesirable To prevent the condition is a signal suppression transistor 160 having a base electrode 161, a collector electrode 162 and an emitter electrode 163 are provided. The collector electrode 162 is in between with the connection point of the diode 107 and the base electrode of the switching transistor 50, the emitter electrode 163 is connected to the connection terminal 108 of the secondary winding 26 and the base electrode 161 is connected to ground 5 via a resistor 165. When charging the ignition capacitor 18, the charging current flows through the resistor 150 from ground 5 in the direction to the connection terminal 108 of the secondary winding 26. The

-23 -

009 8 20/1 36 9

yso 8

developed by the charging current in resistor 150 The voltage drop causes the emitter electrode 163 of the signal suppression transistor 160 to have a voltage that is slightly is less positive than the voltage on the base electrode 161. A base-emitter current therefore flows in the signal suppression transistor 160 when the ignition capacitor 18 is charged. A second switchover pulse occurs at this time on, it is passed through the collector-emitter circuit of the signal suppression transistor 160, which is connected to the Switching transistor 50 is short-circuited, so that the second switching pulse at the switching transistor 50 is ineffective and therefore keeps the switching transistor 40 in the conductive state. There the connection terminal 110 of the switching winding 112 is positive with respect to the connection terminal 111, exerts between the connection terminal 110 and the collector electrode of the signal suppression transistor 160 lying resistor 168 creates an additional positive voltage on collector electrode 162 of the signal suppression transistor 160, so that an additional security for the conductive state of the signal suppression transistor's 160 is given as long as the ignition capacitor 18 is charged. With the secondary winding open the ignition coil effects the inductance-reactance circuit the primary winding 20 of the ignition coil 19 and the ignition capacitor 18 have a ringing effect, which the ignition capacitor 18 in reverse Direction onIWt. The ignition capacitor 18 discharges

- 24 -

09820/136 9

then in the opposite direction through the primary winding 20 _β This causes the controlled silicon rectifier 22 to be extinguished and charges the ignition capacitor 18 in the forward direction via the diode 132, which blocks the opposite high voltage on the ignition capacitor 18 from the anode-cathode circuit of the controlled silicon rectifier 22. Since the ignition capacitor tries to discharge in the forward direction while the controlled silicon rectifier 22 is non-conductive, the voltage at the anode-cathode circuit rises rapidly. A capacitor 134 and a parallel diode 135 and a resistor 136 act as a filter which reduces the voltage build-up, which prevents the controlled silicon rectifier 22 from switching to the conductive state in the anode-cathode circuit due to the strong dE / dt supplied to it .

The diode 116 is a free-wheeling diode, which is parallel to the primary winding 20 to oscillate in to dampen this during the rollover at a spark gap. The resistor 138 is a bleeder resistor through the the ignition capacitor 18 is discharged with the switch 56 open. The thermistor 140 effects temperature compensation. Of the Capacitor 142 is a filter capacitor and the zener diode 144 protects the switching transistor 40 if the ignition coil should be separated from the circuit of the ignition system. In the off

- 25 -

009820/136 9

Leading example are special types of transistors, electrical Polarities and components specified. Modified types of transistors, corresponding Polarities and modified components used! only if the function is the same.

982Q / J369

Claims (3)

*> ■ Γ - 26 - J Patent claims: (1. / ignition system with ignition capacitor with "a dependent on the speed of an internal combustion engine ignition \ signal transmitter, a on the ignition signals responsive converter-i circle, which provided the Aafladespannung for the ignition capacitor which is located in an output circuit of the charging circuit for the ignition capacitor, the primary winding of the ignition coil and this together connecting ignition capacitor switch, characterized in that a circuit is provided which supplies two switching signals of the same polarity for each ignition signal and the circuit a direct current source ^), connecting terminals (16,17) for connecting the signal generator, oil converter (36) with a primary winding (37) and a secondary winding (33), which are connected with opposite polarity to output terminals (28,5) of the circuit, a transistor (80) with a control electrode (81) and two current-carrying electrodes (82,83), the live electrode ^ in series with the primary winding on the direct current source, and one n capacitor (69) and two resistors (67,68), with an RC charging circuit for the capacitor at least the capacitor, the one resistor - 27 - 9 8 2 0/1369 9 b b 81 3 stood (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 the terminals (16,17) ignition signal encountered the capacitor (69) with opposite polarity j with its control electrode (91) and one of its two; current carrying electrodes (92,93) connects to a discharge \ circuit for the capacitor (69) to close via the second resistor (68) «, 2. Ignition system according to claim 1, characterized in that the second switching device is a second transistor (90) with a base electrode (91), an emitter electrode (93) and a collector electrode (92), which is connected to the base-emitter circuit with the connection terminals (16,17) of the Signal transmitter is connected and its collector electrode via the first resistor (67) with the direct current source (8) and is connected to one plate of the capacitor (69), the other plate of which is connected to via the second resistor (68) the direct current source (8) and is connected to the control electrode (81) of the first transistor (80). 3. Ignition system according to claim 1 or 2, characterized by one on the charging current of the ignition capacitor (18) appealing at high engine speed - 28 - 009820/1 369 1958813 Signal suppression circuit (160), which has a parallel path to the converter circuit for the second of each Ignition signal supplied switching signals forms. 9 8 2 0/1369 25th
Blank page