EP0415240A2 - Ignition system for a combustion engine - Google Patents

Abstract

The ignition system consists of a self-oscillating ignition output stage, a miniature ignition coil, a static and / or dynamic detection of the ignition angle and a power pack. The ignition output stage causes the ignition current to be an alternating current and the ignition energy to be supplied to the spark plugs in a current-controlled manner. The ignition timing is determined by the detection of the ignition angle. The entire ignition output stage and additional consumers of a motor vehicle are supplied with electricity by a current and voltage-converting power pack. <IMAGE>

Description

The invention relates to an ignition system according to the preamble of patent claim 1.

The use of alternating current for spark ignition in internal combustion engines is known. The use of alternating current for the ignition has the advantage that the spark discharge at the spark plug can be maintained over any period of time and can thus be easily adapted to the instantaneous requirement of the engine, which increases the efficiency of the internal combustion engine through the more complete use of the fuel mixture and the pollutants reduced in exhaust gas.

DE-OS 1 539 183 describes an ignition arrangement with a primary and secondary circuit of a step-up transformer, the primary circuit of which is designed as a parallel and series resonance circuit. After a rapid discharge in the secondary circuit, this resonant circuit generates an alternating current at the spark plug cathodes. Furthermore, from DE-OS 25 17 940 a capacitor ignition system for internal combustion engines with ferromagnetic resonance is known, in which only after each discharge of the primary-side capacitor, a second control circuit generates an oscillating current in the primary and secondary windings and thus for a predetermined Period of time allows an alternating current to flow at the spark plug.

Another AC ignition arrangement is described in DE-OS 29 34 573. In this ignition system, an oscillator circuit controls a transistor push-pull circuit connected to the primary winding of an ignition coil. This oscillator circuit is controlled by the switch positions of the breaker contacts of an ignition distributor and generates an AC signal with a constant frequency at the spark plugs.

A disadvantage of this known ignition system is that the generation of the alternating current signal requires an input signal triggered by a start pulse, which necessitates additional switching measures for generating the start pulse.

Another disadvantage of these known ignition systems is that the energy supply takes place over a constant ignition period and thus generates an AC signal with constant power at the ignition contacts. This can happen if the conclusion is unfavorable the secondary circuit z. B. if the mixture is not ignited, if the ignition contacts are short-circuited or the spark plug connector is removed, the power supply may be too high, which may damage or even destroy the electrical components of the ignition system.

• 1. Die Zündung des Brennstoffgemisches soll nach der Trigge­rung in kurzer Zeit, möglichst in wenigen µs, erreicht werden.
• 2. Beliebig einstellbare Brenndauer.
• 3. Problemlose statische und dynamische Triggerung.
• 4. Brennspannungstoleranzen, die durch Ionisationsschwankun­gen in den Zündstromnulldurchgängen, Verwirbelung und Druckänderungen des im Zylinderraumes befindlichen Brenn­stoffgemisches auftreten, sollen keinen oder nur einen geringen Einfluß auf den Brennstrom haben.
• 5. Hohe Betriebssicherheit sowohl im Normalbetrieb als auch bei Störfällen, z. B. bei offenem oder kurzgeschlossenem Zündkerzenausgang, über einen großen Temperaturbereich.
• 6. Geringe Hochfrequenzströungen.

The present invention has for its object to provide an ignition system of the type mentioned above, which does not have the disadvantages described and has or enables the following properties:

• 1. The ignition of the fuel mixture should be achieved after the triggering in a short time, if possible in a few µs.
• 2. Any adjustable burning time.
• 3. Trouble-free static and dynamic triggering.
• 4. Burning voltage tolerances, which occur due to ionization fluctuations in the ignition current zero crossings, swirling and pressure changes of the fuel mixture located in the cylinder space, should have little or no influence on the combustion current.
• 5. High operational reliability both in normal operation and in the event of malfunctions, e.g. B. with open or short-circuited spark plug output, over a wide temperature range.
• 6. Low high frequency currents.

According to the invention, this object is achieved by the features specified in the characterizing part of claim 1.

Accordingly, the basic idea of the invention is to switch an ignition output stage (primary and secondary circuit) in such a way that it operates in a current-controlled flyback and forward converter mode.

The blocking and flow time of a switching transistor in the primary circuit of the ignition output stage is controlled as a function of the ignition energy consumed in the secondary circuit in such a way that the ignition current frequency rises with increased energy consumption in the secondary circuit and decreases with reduced energy consumption. The controlled variable, which determines the switch-on cycles of the transistor, is the energy not completely removed from the primary circuit by the secondary circuit, the constant supply of energy to the output circuit being ensured by the current control on a resistor in the primary circuit. As a result, only as much energy is supplied to the primary and thus also the secondary circuit as is necessary for generating an ignition spark and for regulating.

By using an energy recovery diode, the unused energy is fed back into the energy store (battery) and thus causes a smaller consumption of the electrical power.

Circuit technology options are specified with claims 2 to 7. In particular, the ignition of two spark plugs can take place with one ignition output stage (see claim 4). In order to reduce the settling time of the ignition output stage, the actuator controlling the energy supply (ohmic resistance) can be switched by additional circuitry measures (see claims 7 and 8).

The self-oscillating ignition output stage (output circuit) exists consisting of a switch (transistor), an energy recovery diode, a charging coil, a primary resonant circuit capacitor and a secondary circuit coil, which is connected in series to a spark plug capacitance. The function of the output circuit is comparable to a band filter. Two states are electrically possible:

1. Ignition failed:

In this case, the secondary circuit is supercritically coupled to the primary circuit by the mutual inductance because of its approx. 50% coupling. This ensures that the high voltage in the secondary circuit is very quickly available in full within a few periods.

2. Ignition successful:

In this case, the secondary circuit is loosely coupled to the primary circuit due to the strong damping. This guarantees a quasi constant current supply almost independent of the ignition voltage.

• a) Die erforderliche Zündspannungsamplitude wird schnell erreicht, so daß auf einen Verteiler, der erst bei bzw. nach Erreichen die Zündkerze an Zünd­spannung legt, verzichtet werden kann.
• b) Fehlt z. B. wegen abgezogenen Zündsteckers die Kapazität im Sekundärkreis, so steht zum Schutz der Zündspule nicht die volle Hochspannung am sekundär­seitigen Ausgang an, wodurch eine höhere Betriebs­sicherheit des Zündsystems erreicht wird.
• c) Bei kurzgeschlossener Zündkerze sowie im Normal­betrieb bei unterschiedlichen Zündspannungen ist der Zündstrom stets auf einen für das Zündsystem unschädlichen Wert begrenzt.

The circuit arrangement according to the invention, which also takes the spark plug capacity into account in the non-ignited state, offers the following safeguards and possibilities:

• a) The required ignition voltage amplitude is reached quickly, so that a distributor that only applies the ignition plug when or after reaching the ignition voltage can be dispensed with.
• b) Missing z. B. due to the detached ignition plug, the capacity in the secondary circuit, so to protect the ignition coil is not the full high voltage at the secondary output, whereby a higher reliability of the ignition system is achieved.
• c) When the spark plug is short-circuited and in normal operation with different ignition voltages, the ignition current is always limited to a value that is harmless to the ignition system.

This technique of the self-oscillating ignition stage described above allows a considerable reduction in the volume of an ignition coil, since the total spark energy is allocated to the spark plug over a longer period of time and because the transmission frequency is high and the circuit operates in both the blocking and the flow mode.

Another advantage of this ignition output stage is that only a coupling of approximately 50% is required for the construction of the ignition coil. This feature allows such a miniature ignition coil to be inexpensive and easy to manufacture.

Since each spark plug is provided with a miniature ignition coil and because the circuit operates in flow and flyback mode and thus the high voltage is available almost immediately after triggering, a distributor can be dispensed with without any problems. Particularly suitable, small-sized and rationally producible ignition coils are the subject of claims 10 to 17.

With the invention according to claims 18 to 20 measures for control, in particular triggering of the ignition paths, are also proposed.

Various methods are known per se for triggering the individual ignition paths. From DE-OS 36 30 272 A1, a device for controlling an internal combustion engine is known, in which the position of a sensor disk connected to a shaft of the internal combustion engine, which has a perforation designed as a marking, is registered by a fixed recording segment. By means of an inductive sensor, e.g. Working according to the eddy current principle, pulses are obtained that are evaluated electronically. A control and regulating circuit then generates the switch-on and switch-off signals for the individual ignition branches with these pulses. This known method is also suitable for triggering high-frequency AC ignition. A disadvantage of the dynamic detection of the ignition timing mentioned above is that a movement of the encoder disk is necessary to determine the position in order to clearly determine the position of the camshaft or crankshaft.

According to the proposal according to the invention, a wheel is mounted on the camshaft to record the correct triggering time for the ignition, which carries a clearly identifiable code on its surface, which code is scanned by a sensor. The sensor scans, for example, inductively or optically. For example, a 10-bit Gray code can be arranged on the peripheral surface of a camshaft gear, which is scanned by an inductive multifunction sensor with integrated electronics and supplies electrical signals corresponding to the position of the camshaft gear. An improved resolution is achieved by executing the code non-linearly, ie a high resolution only in the area from top dead center is provided. By means of this sensor and transmitter arrangement, a static and / or dynamic detection, for example of the crankshaft angle, is possible in order to thus determine the position of the pistons and the ignition sequence for the individual cylinders of the internal combustion engine. This advantageously enables a self-start without using a starting device, e.g. B. an electric starter motor possible.

The components required for the ignition system according to the invention, in particular for the control and regulating circuit and the sensor for static and / or dynamic detection of the crankshaft angle, can be produced in a conventional manner directly using a known low-voltage source, e.g. B. a DC battery of 12 volts can be fed. The disadvantage of such a low voltage supply is that the supply of electrical consumers that require a high operating voltage, such as. B. headlights with high-pressure gas discharge lamps or the ignition system described above, is only possible with an unfavorable efficiency. This disadvantage can be advantageously countered according to the invention by using a switched-mode power supply, that is to say an inverter with a transformer, in a motor vehicle. When using a battery with a terminal voltage of 6 to 18 volts, output voltages of z. B. 150 volts with better efficiency than when using a low voltage supply for the electrical consumers and their supply network in the motor vehicle.

The invention is explained below with reference to exemplary embodiments in the drawing.

• Figur 1 eine schematische Gesamtdarstellung der erfin­dungsgemäßen Zündanlage,
• Figur 2a eine Schaltungsanordnung einer Zündendstufe nach einem ersten Ausführungsbeispiel,
• Figur 2b eine Schaltungsanordnung einer Zündendstufe nach einem zweiten Ausführungsbeispiel,
• Figur 2c ein Ersatzschaltbild der in Figur 2a und Figur 2b dargestellten Zündendstufen,
• Figur 3a eine Schaltungsanordnung einer Zündendstufe nach einem dritten Ausführungsbeispiel,
• Figur 3b ein Ersatzschaltbild der in Figur 3a dargestell­ten Schaltungsanordnung,
• Figur 4a ein Zeitdiagramm des Spannungsverlaufes der Drainspannung U_D des Schalttransistors TR1 bzw. TR2 in den Schaltungen gemäß Figur 2 bzw. 3,
• Figur 4b ein Zeitdiagramm der Sekundärkreisspannung UH entsprechend der Drainspannung gemäß Figur 4a,
• Figur 4c ein Zeitdiagramm des Drainstroms I_D des Schalttransistors entsprechend der Drainspannung gemäß Figur 4a,
• Figur 5a ein Zeitdiagramm des Drainstroms I_D des Schalttransistors im Zündfall,
• Figur 5b ein Zeitdiagramm der Brennspannung U_B an der Zündkerze im Zündfall,
• Figur 5c ein Zeitdiagramm der Drainspannung U_D des Schalttransistors im Zündfall,
• Figur 6 eine Schaltungsanordnung nach einem weiteren Ausführungsbeispiel für drei Zündwege für je zwei Zündkerzen,
• Figur 7 eine Schaltungsanordnung eines Zündendstufenmo­duls nach einem Ausführungsbeispiel,
• Figur 8 eine Schaltungsanordnung eines Zündendstufenmo­duls nach einem weiteren Ausführungsbeispiel,
• Figur 9 eine schematische Darstellung einer gesamten Zündendstufe nach einem Ausführungsbeispiel,
• Figur 10 eine teilweise geschnittene Seitenansicht einer zusammengesetzten Miniaturzündspule nach einem Ausführungsbeispiel,
• Figur 11a - 11c die Einzelteile der Zündspule gemäß Figur 10 in Explosionsdarstellung, nämlich
  • Figur 11a das Spulengehäuse,
  • Figur 11b den Spulenkern und
  • Figur 11c den Spulenkörper,
• Figur 12 schematische Darstellung einer Triggervorrichtung zur statischen und/oder dynamischen Erfassung des Kurbelwellenwinkels nach einem Ausführungsbei­spiel,
• Figur 13 schematische Darstellung einer Triggervorrichtung zur statischen und/oder dynamischen Erfassung des Kurbelwellenwinkels gemäß einem weiteren Aus­führungsbeispiel und
• Figur 14 eine Schaltungsanordnung für ein Schaltnetzteil.

Show it:

• FIG. 1 shows an overall schematic representation of the ignition system according to the invention,
• FIG. 2a shows a circuit arrangement of an ignition output stage according to a first exemplary embodiment,
• FIG. 2b shows a circuit arrangement of an ignition output stage according to a second exemplary embodiment,
• FIG. 2c shows an equivalent circuit diagram of the ignition output stages shown in FIG. 2a and FIG. 2b,
• 3a shows a circuit arrangement of an ignition output stage according to a third exemplary embodiment,
• FIG. 3b shows an equivalent circuit diagram of the circuit arrangement shown in FIG. 3a,
• FIG. 4a shows a time diagram of the voltage profile of the drain voltage U _{D of} the switching transistor TR1 or TR2 in the circuits according to FIGS. 2 and 3,
• FIG. 4b shows a time diagram of the secondary circuit voltage UH corresponding to the drain voltage according to FIG. 4a,
• FIG. 4c shows a time diagram of the drain current I _{D of} the switching transistor corresponding to the drain voltage according to FIG. 4a,
• FIG. 5a shows a time diagram of the drain current I _{D of} the switching transistor in the event of ignition,
• FIG. 5b shows a time diagram of the internal voltage U _B at the spark plug in the event of ignition,
• FIG. 5c shows a time diagram of the drain voltage U _{D of} the switching transistor in the event of ignition,
• FIG. 6 shows a circuit arrangement according to a further exemplary embodiment for three ignition paths for two spark plugs,
• FIG. 7 shows a circuit arrangement of an ignition output stage module according to an exemplary embodiment,
• FIG. 8 shows a circuit arrangement of an ignition output stage module according to a further exemplary embodiment,
• FIG. 9 shows a schematic illustration of an entire ignition output stage according to one exemplary embodiment,
• FIG. 10 shows a partially sectioned side view of an assembled miniature ignition coil according to one exemplary embodiment,
• 11a-11c the individual parts of the ignition coil according to FIG. 10 in an exploded view, namely
  • FIG. 11a the coil housing,
  • Figure 11b the coil core and
  • 11c the coil former,
• Figure 12 is a schematic representation of a trigger device for static and / or dynamic detection of the crankshaft angle according to one embodiment,
• FIG. 13 shows a schematic illustration of a trigger device for static and / or dynamic detection of the crankshaft angle according to a further exemplary embodiment and
• Figure 14 shows a circuit arrangement for a switching power supply.

The ignition arrangement according to the invention consists of the components shown schematically in FIG. 1, which are:
- a low voltage supply (BAT),
- a central switching power supply (UF1),
- High voltage generating ignition output stages (ZST), according to the number of cylinders
- and miniature ignition coils (ZSP) for each spark plug.

The ignition output stage according to the invention shown in Fig. 2a consists of a primary and secondary resonant circuit. The primary resonant circuit has a control and regulating circuit 2 with a trigger input 4, a trigger output 6 and a supply line 8, and the primary winding P1 of an ignition coil. A resonant circuit capacitor C1 is located in series with the primary circuit coil P1, and an energy recovery diode D1 is arranged in parallel therewith. A transistor TR1 is connected on the drain side to the capacitor C1 and the energy recovery diode D1. On the source side, transistor TR1 is connected to ground via a current limiting resistor R1. A supply line 10 connects the transistor on the source side to the current limiting resistor R1 and the open-loop and closed-loop control circuit 2. On the secondary side, the secondary coil (S1) is in series with the winding and ignition capacitance CW, as illustrated by the equivalent diagram in FIG. 2c. 2b, an output stage with galvanically isolated inductive coupling is provided.

A complete circuit of an ignition stage with three ignition paths for two spark plugs each, i.e. for a six-cylinder engine. B., is illustrated with Fig. 6.

The supply of two spark plugs Z1, Z2 with a common ignition output stage is shown in FIG. 3a. With such a connection of the secondary circuit, the effective winding and spark plug capacitance CW is preferably reduced by a factor of 2, as is illustrated in the equivalent circuit diagram in FIG. 3b.

The basic function of the ignition output stage according to the invention is based on time diagrams in FIGS. 4a to 4c so far and in FIGS. 5a to 5c for the above. Exemplary embodiments of the ignition output stage explained.

The function of the self-oscillating ignition output stage is first explained for the non-ignited case (time diagram in FIGS. 4a to 4c).

Here, the steady state is assumed with sufficient battery voltage. The voltage at point A in the circuit according to FIG. 6 releases the operation with a low level as soon as the amplifier OP1 is switched through. A trigger input, e.g. B. Trigger input 3, are connected to ground according to the control. Because the reference voltage at point B is more positive than the voltage at the inverting input of the amplifier OP4, the transistor T30 is turned on. A drain current I _D begins to flow (Figure 4c, time period t1). The voltage drop across resistor R37 rises until the voltage at the inverting input (-) of amplifier OP4 becomes more positive than the reference voltage at point B.

At this time, transistor T30 is blocked. The energy contained in the SP30 storage coil excites the entire output circuit to vibrate. Part of the energy is transferred to the capacitor C33 of the primary area (C1 or C2 in the equivalent circuit diagram 2c or 3b) and the other part to the capacitance CW of the secondary circuit (time period t2, Fig. 4a and 4b).

The voltage U _D across the capacitor C33 rises sinusoidally until there is no more energy in the storage coil. In the time period t3, the capacitively stored energy is fed back to the inductance L1 until the voltage on the capacitor C33 is equal to zero. At this point in time (beginning of time period t4), the storage coil SP30 releases its existing energy into the circular capacitor CW on the secondary side. On the primary side, this is not possible analogously for C33, since the voltage U _D at the drain from transistor T30 cannot become negative because the internal diode (energy recovery diode D1 or D2 in FIGS. 2a, 2b, 3a) becomes conductive. The energy present in the primary inductance L1 is returned to the vehicle electrical system via the diode D30 (time period t4, see Figure 4c).

The secondary circuit can continue to oscillate in this time segment t4 (see U _H in FIG. 4b). Its frequency is somewhat higher than before, because the leakage inductance L σ (FIG. 2c, FIG. 3b) is now parallel to the mutual inductance M. (see Fig. 2c, 3b). During this time period t4, transistor T30 is turned on again because the same voltage conditions are present as at the beginning of time period t1. When the energy of inductor L1 is completely given to the voltage source (vehicle electrical system), a new cycle starts.

To understand the circuit, it should be mentioned that the transistor T30 is only blocked if the voltage at the inverting input (-) of the amplifier OP4 is more positive than the reference voltage at point B. This case always occurs when the charging current I _{D is} one limit reached by resistor R37. This current control guarantees a constant supply of energy to the primary inductance L1, whereby the energy - apart from minor losses - is completely returned to the vehicle electrical system in the event of non-ignition. The blocked state of transistor T30 is maintained by the voltage drop across resistor R36 as long as the voltage U _D at the drain of transistor T30 is more positive than the battery voltage.

The described function of self-excitation does not change for the ignition, because the inductive coupling between primary and secondary inductance of approx. 50% prevents total damping of the primary circuit by the strongly damped secondary circuit. For the ignited case, the following functions then result:

Because of the combustion current now flowing through the spark plug, considerably less energy from the voltage source, that is to say into the vehicle electrical system, is now returned (FIG. 5a). The time period t4 is shortened significantly. An advantage of this circuit concept is that only as much energy is returned as is still available after the ignition phase. This behavior enables the desired current to be supplied largely independently of the operating voltage U _B in a large range. If the burning voltage U _{B is} large, a large proportion of the energy in the arc of the spark plug is converted into heat. In this case, less residual energy is returned to the voltage source. The result is that
the time period t4 becomes shorter, the ignition frequency increases and the current consumption increases.

In the opposite case, that is to say for low operating voltage U _B , the inverse behavior applies, that is to say that
the time period t4 increases, the ignition frequency decreases and the current consumption decreases.

In the exemplary embodiment explained above, there are different primary and secondary circuit frequencies.

With suitable circuit dimensioning, for example, the primary freewheeling frequency is approximately 18 kHz and the secondary frequency:
43.5 kHz with open primary circuit and
60 kHz with short-circuited primary circuit.

The basic frequency with spark plug termination is approximately 20 kHz with a burning voltage of 900 Vpp.

So immediately after the switch-on signal of the control and Control circuit, the high voltage at the spark plug is available in full, it is advantageous if the drain current I _D through the drain-source path of the transistor T30 is greater than in the fully steady state for a defined period of time. To achieve this, the actual measured value of the drain current-proportional voltage at point C is reduced in the circuit according to FIG. 7 by means of a bistable flip-flop FF1 which drives the gate of the transistor T40. The current amplitude is set by the resistor R40 in such a way that the stored energy in the primary inductance L1 is sufficiently large to replace the residual energy not yet present in the output circuit when switching on. As a result, the maximum high voltage U _H is reached during the first oscillation period.

The flip-flop FF1 can be reset by the negative edge (trailing edge) of the first current pulse. The resetting of the flip-flop FF1 can also be made dependent on whether an ignition has taken place or not. The information for this can e.g. can be derived from the changing frequencies.

According to a further preferred exemplary embodiment, which is illustrated in FIG. 8, FF2 can be effected by means of an additional monostable flip-flop. that the bistable flip-flop FF1 can only be reset during the period in which the transistor current I _D would flow, provided that an ignition would have taken place. This arrangement has the advantage that the ignition voltage U _H rises further in the case of very heavily contaminated spark plugs, thereby providing a voltage reserve for heavily worn and contaminated spark plugs.

The overall structure of an ignition output stage (see FIG. 9) with an ignition module IZM with an integrated circuit and an ignition coil ZSP is shown in FIG. 9. The complete switching of the ignition module with a high degree of integration allows inexpensive manufacture and high operational reliability.

The miniature ignition coil to be used advantageously in cooperation with the ignition output stages explained above is shown in detail in FIGS. 10 and 11a-11c. The miniature ignition coil consists of three individual components, namely the coil body 20, the coil core 22 and the coil housing 24. The coil body 20 has a cylindrical basic shape, on one end face of which a socket 26 is attached in one piece. This socket 26 is surrounded by a circumferential cylinder wall 28 which acts as a protective cap and brings about a force-fitting and precise fit on the spark plug.

Individual chamber segments 30a to 30g, 32 are formed on the lateral surface 29 of the bobbin 20 by a plurality of circumferential segment ribs. The chamber segment 32 with the largest chamber rib spacing 1 preferably accommodates the coil winding of the low-impedance primary circuit coil, since the primary circuit can be designed with larger tolerances in the winding structure and can be designed without a chamber for better use of space. The coil winding of the high-resistance secondary coil is preferably introduced into the smaller-spaced chamber segments 30a to 30g. An advantage of this chamber winding technique of the secondary circuit is that a higher dielectric strength is achieved and smaller winding tolerances are easier to manufacture. The line connections 34 for the primary circuit are led out of the coil body 20 at the end.

To accommodate the coil core 22, the coil body 20 has a concentric bore 33 (see FIG. 11c).

The coil core 22 is mushroom or T-shaped. This shape allows simple assembly on the one hand and on the other hand causes magnetic shielding and increases the quality of the primary circuit. The coil core 22 is preferably made of ferrite, which advantageously shows no signs of saturation up to a temperature of 200 ° C.

To fix the coil core 22 in the coil body and to protect the coil windings, the coil housing 24 for the coil body 20 with the coil core 22 inserted (see FIG. 11a) is designed in a cap or pot shape. To protect the electrical leads against mechanical stress, a pipe socket 36 is attached to the coil housing 24 on its upper cover.

In the final assembled form (see FIG. 10), the coil body with the coil housing 24 is encapsulated in a watertight manner, which advantageously increases the corrosion resistance. The potting compound 38 preferably extends over the chamber segments 30a to 30g receiving the secondary windings. The potting material used is preferably made of silicone. Plastoferrite is suitable for the coil housing 24, which e.g. is enriched with conductive carbon black, which creates a magnetic and electrostatic shield against external electromagnetic fields. Overall, the simple construction of the ignition coil 22 permits cost-effective production and the small volume of the ignition coil 22 allows it to be placed directly on the spark plugs, which increases the operational reliability of the ignition system and results in a low HF interference.

The angular position is used to trigger individual ignition paths a crankshaft or camshaft by means of a coding disk 40, 42 fixedly connected to it, as shown in FIG. 12 or FIG. 13. 12 shows a code that can be used to trigger 3 ignition paths. The binary code of the radially arranged coding tracks 44a, b, c is read out by means of an inductive sensor 46 and evaluated in the electronics 48. This electronics provides at its output 50 the trigger signals required for the individual ignition paths. The code is expediently designed in its phase position for the highest engine speed, so that the downstream electronics 48, depending on the speed, feeds the trigger signal to the ignition output stages with a delay.

A fully digital circuit in which the ignition phase is evaluated directly by means of an on-board computer 52 is shown in FIG. 13. The code pattern 53 is on the outer surface 42 of the rotationally fixed z. B. arranged with the camshaft connected code wheels. A 10-bit Gray code is preferably used as the code. B. is read by an inductive multifunction sensor 54 or by an optical scanning device. The signals are in a downstream integrated electronics 52 e.g. an on-board computer for determining position z. B. evaluated individual piston positions. This information is used for triggering the individual ignition output stages, as well as for dosing and for controlled direct injection of the fuel mixture into the cylinder rooms.

With such a coding disk, the absolute position of the crankshaft or camshaft can already be determined statically, that is to say in retirement, which makes it possible to start (start) the internal combustion engine from the idle state without an electric starter device (starter) makes.

The voltage and power supply of electrical devices can be done by means of a switching power supply (DC-DC converter). The circuit arrangement of a preferred exemplary embodiment is shown in FIG. 14. This is a known circuit arrangement of a secondary regulated single-ended flyback converter.

Claims (23)

1. Ignition system for an internal combustion engine, at least consisting of a DC voltage source, an ignition coil with primary and secondary winding, a controllable semiconductor switch between the ignition coil and voltage source and a spark plug arranged in the circuit of the secondary winding, the primary winding with a capacitor forming a first resonant circuit, the primary circuit, and the secondary winding with its winding capacity and the spark plug capacity form a second resonant circuit, the secondary circuit, for generating a bipolar ignition current during the ignition phase, and further comprising a triggerable control and regulating circuit for controlling the semiconductor switch, characterized in that the primary and secondary circuits follow Type of a band filter when ignition is not supercritical and loosely coupled after ignition that an energy recovery diode is arranged parallel to the capacitor of the primary circuit et is and that the primary circuit is dimensioned and controlled by the control and regulating circuit such that it works in the current-controlled flyback and forward converter operation. 2. Ignition system according to claim 1, characterized in that the primary winding (P1) in series with a resonant circuit capacitor (C1), an energy recovery diode (D1), a transistor (TR1) and a current limiting resistor stood (R1) is that the transistor (TR1) on the drain side with the cathode of the diode (D1) and the capacitor (C1) and on the source side with the resistor (R1) and a feed line (10) with the control and regulating circuit (2) is connected that the primary winding (S1) of the ignition coil is electrically conductively connected to the secondary winding (S1), that the secondary winding (S1) is in series with the spark plug capacitance (Z1), that the primary winding (P1) via a feed line (8) a voltage supply and the control and regulating circuit (2) is connected and that the control and regulating circuit (2) has a trigger input (4). 3. Ignition system according to claim 1 and / or 2, characterized in that the primary winding (P2) and secondary winding (S2) of the ignition coil are only coupled inductively. 4. Ignition system according to at least one of claims 1 to 3, characterized in that the secondary winding (S2) of the ignition coil is in series with a first spark plug capacity (Z1) and a second spark plug capacity (Z2). 5. Ignition system according to at least one of claims 1 to 4, characterized in that the ignition output stage has an ignition module (ZM3), the at least one amplifier (OP4), a transistor (T30), an energy recovery diode integrated in the transistor (T30), a Ignition coil (SP30), a primary circuit capacitance (C33) and four resistors (R34, R35, R36, R37)), the input (-) of the amplifier (OP4) in series with the diode (D28) and with a drive line (A ) is connected, the output of the amplifier (OP4) driving the gate of the transistor (T30) via a driver stage and the drain-source path of the transistor (T30) is in series with the primary winding (L1) and the resistor (R37), that the transistor (T30) on the source side via the series resistors (R34 and R35) with the inverting Input (-) of the amplifier (OP4) and the cathode of the diode (D28) is connected so that the transistor (T30) on the drain side with the coil winding (L1) with the capacitance (C33) and the resistor (R36) connected to the internal energy return diode is connected and that the secondary winding (L2) of the ignition coil (SP30) is connected in series with two spark plugs. 6. Ignition system according to at least one of claims 1 to 5, characterized in that the resistor (R34) and the resistor (R35) together with a to the drain-source path of a transistor (T40) connected in series resistor (R40) are that the transistor (T40) is connected to ground on the source side and that the gate of the transistor (T40) can be controlled via a resistor (R41) from the output of a flip-flop (FF1) and its control input (S) via a diode (D30 ) is connected to the output of an inverting amplifier (IC28), that the reset input (R) of the flip-flop (FF1) is connected to the source side of the transistor (T30) via an amplifier and that the flip-flop (FF1) connects the transistor (T40) drives such that it becomes conductive via its drain-source path with the resistor (R40), as a result of which the electrical power output in the primary circuit is increased. 7. Ignition system according to at least one of claims 1 to 6, characterized in that the reset input of the flip-flop (FF1) from the output of an AND block (UN1) is controlled, the input (E1) of the AND component (UN1) from the output of a monostable flip-flop (FF2) and the second input (E2) of the AND component (UN1) with the input of the monostable flip -Flops (FF2) and the source side of the transistor (T30) is connected via an amplifier such that the bistable flip-flop (FF1) can be reset as a function of the drain current (I _D ) of the transistor (T30). 8. Ignition system according to at least one of claims 1 to 7, characterized in that the burning duration of the ignition current can be reduced with increasing the speed of the internal combustion engine. 9. Ignition system according to at least one of claims 1 to 8, characterized in that the ignition current frequency is preferably greater than 16 kHz. 10. Ignition system according to at least one of claims 1 to 9, characterized in that the entire self-oscillating ignition output stage consists of an integrated circuit structure (IZM) and a miniature ignition coil (ZSP). 11. Ignition system according to at least one of claims 1 to 10, characterized in that the ignition coil preferably consists of an integrally manufactured coil body (20), an integrally manufactured coil core (22) and an integrally manufactured coil housing (24). 12. Ignition system according to at least one of claims 1 to 11, characterized in that the coil core (22) is mushroom-shaped. 13. Ignition system according to at least one of claims 1 to 12, characterized in that the coil body (20) is connected to the coil housing (24) by a casting compound (38). 14. Ignition system according to at least one of claims 1 to 13, characterized in that the coil former (20) is preferably cast with potting compound (38) in the region of the secondary winding. 15. Ignition system according to at least one of claims 1 to 14, characterized in that the casting compound used (38) is silicone. 16. Ignition system according to at least one of claims 1 to 15, characterized in that the coil housing (24) consists of plastoferrite. 17. Ignition system according to at least one of claims 1 to 16, characterized in that the plastoferrite is enriched with conductive carbon black. 18. Ignition system according to at least one of claims 1 to 17, characterized in that the width (1) of the chamber segment (32) for the primary winding is greater than the width (k) of the chamber segments (30a - 30g) for the secondary winding. 19. Ignition system in particular according to one of claims 1 to 18, in which the ignition timing and duration are derived from the rotational speed and / or the angular position of the crankshaft or camshaft, characterized in that a wheel (40th , 42) is rotatably connected, the surface of which clearly identifies the angular position Code (44a, b, c) which is scanned by a sensor (46, 54) and converted into signals controlling the ignition by means of an electronic circuit (48, 52). 20. Ignition system according to claim 19, characterized in that the code is non-linear, the areas of high code resolution are assigned to the areas of the top dead centers of the pistons. 21. Ignition system according to claim 19 and / or 20, characterized in that the code is a 1-step Gray code (53). 22. Ignition system according to at least one of claims 19 to 21, characterized in that a current and voltage converter (UF1) is used for part of the electrical supply of a motor vehicle. 23. Ignition system according to at least one of claims 19 to 22, characterized in that the voltage or current converter (UF1) input voltages in the range of 6 volts - 18 volts and stabilized output voltages adapted to the needs of the electrical consumers, in particular in a range of 5 Volts - 300 volts.

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