DE1464052B2 - Contactless ignition arrangement for internal combustion engines - Google Patents

Description

however, that there is a strong mutual inductance between the primary winding and the secondary winding must be present in order to generate a high-frequency voltage with sufficient energy for ignition. Such a large mutual inductance, however, with regard to the fact that their temporal Change in the voltage induced on the secondary side is significant at high frequencies to changes in the ignition time, and besides, the high voltage cannot be generated at the moment in which the ignition time is reached.

From the German Auslegeschrift 1 102 483 an ignition arrangement is also known in which the primary current of the ignition coil is controlled by a phototransistor, that of a fixed one Light source from a rotating with a fixed ratio to the speed of the internal combustion engine Aperture is illuminated. The practical use of this known ignition arrangement in motor vehicles fails, however, because there is no light source that can cope with the inevitable harsh conditions Operations in a motor vehicle would have grown over the long term or over a longer period of time could ensure adequate constant lighting under these conditions.

From the German utility model 1849 516 there is also an ignition arrangement for internal combustion engines known, in which the excitation of the primary winding of the ignition coil via a with a Containing permanent magnets rotating depending on the speed of the internal combustion engine Pulse generator is controlled, which supplies power to the primary winding of the ignition coil briefly interrupted in each case for the triggering of an ignition process, during the rest of the time, however Maintained undiminished.

The invention is based on the object of providing a contactless ignition arrangement of the type mentioned at the beginning Kind to train that they have the usual, with conventional mechanical breakers working ignition arrangements allows matched operation in which the ignition spark generation with interruption of the current flowing through the primary winding of the ignition coil and a precise determination of the ignition point is guaranteed over a long period of operation.

This object is achieved according to the invention in that the secondary coil of the control transformer is connected to the primary winding of the ignition coil via a pulse shaper, which controls the flow of current interrupted by the primary winding of the ignition coil and an ignition voltage in its secondary winding induced as soon as its output voltage exceeds a predeterminable value.

In the case of the ignition arrangement designed according to the invention, the high-frequency vibrations are only for generating a control signal for the current flow through the primary winding of the ignition coil controlling circuit used, the inductive coupling between primary coil and secondary coil of the control transformer can be low, and therefore the ignition time remains - regardless of the speed of rotation the metal disc and thus changes in the speed of the internal combustion engine - always constant. Accordingly, the ignition time is also not influenced by changes in the mutual coupling between the primary coil and the secondary coil of the control transformer as a result of the rotational movement of the metal disc, and in addition, there are no deviations in the Ignition time as a function of changes in the engine speed, so that it is possible is able to determine the ignition point with high accuracy and in this way the performance of the Increase internal combustion engine. Another advantage of the invention is that of a Coil to the other energy to be transmitted is only small, so that the whole device is laying down the ignition point can be made in a compact design and replaceable, and finally leads the combination of the means for determining the ignition time with a semiconductor circuit for control of the current flowing through the primary winding of the ignition coil to the possibility of the ignition high voltage to generate with high accuracy at the ignition point.

An expedient embodiment of the invention is characterized in that with the high-frequency oscillator and a voltage source is connected to the pulse shaper stage, the output signal of which its amplitude depends on the speed of the internal combustion engine and on that in the Secondary coil of the control transformer induced voltage determines the ignition timing. At this Design changes the voltage induced in the secondary coil of the control transformer an increase in the speed of the internal combustion engine automatically, and it comes to an automatic Advancing the ignition point.

Another development of the invention is characterized in that the metal disc has slots of adjustable width. A change in the slot width leads to a change in the in the secondary coil of the control transformer induced voltage and thus a control of the duration the current flowing through the primary winding of the ignition coil.

To further explain the invention, an illustrated in the drawing is shown below Embodiment for an ignition arrangement according to the invention described in more detail. It shows 1 shows a block diagram for part of an ignition arrangement according to the invention,

F i g. 2 to 4 pulse diagrams for different points in the circuit according to FIG. 1, F i g. 5, 6 and 7 a section through and two

Top views of part of the circuit according to FIG. 1, F i g. 8 is a timing diagram showing the change

the signal voltage in the circuit of FIG. 1 illustrates

F i g. 9 is a plan view of a differently designed rotatable metal disk, 10 shows a block diagram of an exemplary embodiment for the entire ignition arrangement,

11 is a circuit diagram of the arrangement according to Fig. 10,

Fig. 12 is a circuit diagram for another embodiment the constant voltage source,

13 pulse diagrams for individual points of the circuit according to FIG. 10.

Fig. 1 shows one for determining the ignition point serving device 1 and a high frequency generator 2, its frequency and amplitude are constant regardless of the engine speed. The facility also contains 1 to the output of the high frequency generator

Rators 2 connected first induction coil 3 and a second induction coil 4. The in the latter Coil induced voltage is amplified and used as an output signal.

The coils 3 and 4 are - as shown in FIG. 5 to 7 - opposite each other on one IsolierstoffträgerS arranged. A rotating metal disc 6 is arranged in such a way that it moves into the area between engages the two coils.

The output of the device 1 used to determine the ignition point is sent to a pulse shaper stage 7 connected, and also the device 1 and the pulse shaper 7 are connected to a Constant voltage source 8 connected. The output signal of the pulse shaper 7 is a Amplifier 9, which is connected to the primary winding 11 of an ignition coil 10, is supplied.

The pulse shaper 7 is used to convert the output signal of the device 1 into a square pulse short rise and fall times to transform; it consists of a Schmitt trigger or a monostable Multivibrator.

The amplifier 9 is a DC voltage amplifier or a capacitor discharge amplifier in which the voltage of a converter is used to charge a capacitor and the electrical charge of the capacitor is used.

The details of the circuit of the arrangement according to the invention emerge from FIG.

The induction coil 3 of the high-frequency generator 2 is connected with its one end via the collector-emitter path (38 c, 38 e) of a transistor 38 to one pole A of a DC voltage source 12 and with its other end via the collector-emitter path (13 c, 13 e) of a transistor 13 and a resistor 14 are connected to the other pole B of this DC voltage source 12. A resistor 15 and a capacitor 16 are parallel between the base 13 & of the transistor 13 and one end of the coil 3. A capacitor 17 is also located between the emitter 13 e and the collector 13 c of the transistor 13 a resistor 18 lies between the base 13 b of the transistor 13 and the pole B of the direct voltage source 12. Furthermore, a capacitor 19 is connected between one end of the coil 3 and the emitter 13 e of the transistor 13.

One end of the second coil 4 is connected to the base 20b of a transistor 20, while the other end of this coil 4 is connected to the pole B of the DC voltage source 12 via a resistor 21 and a capacitor 22 connected in parallel. The emitter 2Oe of the transistor 20 is connected to the pole B , while the collector 20c of the transistor 20 via a resistor 23 to which a capacitor 24 is connected in parallel, and the collector-emitter path of the transistor 38 to the pole A of the DC voltage source 12 is connected.

The pulse shaper stage 7, which converts the voltage induced in the coil 4 into square-wave pulses, contains transistors 25 and 26, the emitters 25 e, 26 e of which are connected via a common resistor 27 to the pole B of the voltage source. The base 25 & of the transistor 25 is connected to the collector 20c of the transistor 20 via a resistor, while the collector 25c is connected to the pole A of the DC voltage source 12 via a resistor 29 and the collector-emitter path of the transistor 38. The base 26 b of the other transistor 26 is connected to the collector 25 c of the transistor 25 via a resistor 30 and a capacitor 31 connected in parallel and is at the same time connected to the poll? connected. The collector 26c is connected to the pole A via a resistor 33 and the collector-emitter path of the transistor 38.

The constant voltage source 8 contains a resistor 34 which is connected between the collector 38 c of the transistor 38 and the pole B of the DC voltage source 12. The base 36 b of the transistor 36 is connected to a tap of the resistor 34. The emitter 36 e of the transistor 36 is connected on the one hand via a Zener diode 37 and the collector-emitter path of the transistor 38 to the pole A and on the other hand via a resistor 39 to the pole B of the DC voltage source 12, while the collector 36 c of the Transistor 36 connected to the base 38 b of transistor 38- \ ^. sen is.

The amplifier 9 contains a Zener diode 39, which is connected on the one hand to the output of the circuit 7, ie to the collector 26 c of the transistor 26 and on the other hand via a resistor 40 to the base 41 b of a first transistor 41. The collector 41 c of this transistor 41 is connected to the pole A of the DC voltage source 12 via a resistor 42. The base 436 of a second transistor 43 is also connected to the preceding stage 41 and to the emitter 41e of the transistor through a resistor 44 to the terminal B of the DC voltage source. The collector 43 c of the transistor 43 is connected via a resistor 45 to the pole Λ of the DC voltage source. The base 46 & of a transistor 46, which is in series with the primary coil 11 of the ignition coil device 10, is connected to the emitter 43 e of the transistor 43 of the previous stage and via a resistor 47 to the pole 2? connected to the DC voltage source. The collector 46c is connected to the pole A via the primary coil 11 and a resistor 48. A secondary coil 49 of the ignition device 10 is connected to one end of the primary coil 11, the other terminal of which is connected to the pole A via a spark plug 50.

With this construction of the circuit, the coil 3, which is connected to the output of the high-frequency generator 2 is connected, a high-frequency current with constant amplitude (Fig. 2) is supplied. the The voltage induced in the second coil 4 is amplified for use as an output signal. The rotatable metal disk 6 crosses the space between the two on the insulating material carrier 5 attached coils 3 and 4 at time intervals given by constant angles of rotation and thus shields the coil 4 from the high-frequency field generated by the coil 3. Located the disk 6 in the in F i g. 7 illustrated angular position, then in the coil 4 a constant voltage induced, the amplitude of which is determined by the shape and position of the coils 3 and 4 is. If the disk 6 then gets into the position shown in FIG. 6, the coil 4 compared to the high frequency generated by the coil 3

Quenzfeld largely shielded, so that the voltage induced in the coil 4 is significantly reduced.

The voltage induced in the coil 4 is not as in an alternator of the speed proportional to the internal combustion engine, but is determined by the frequency of the high-frequency generator 2 certainly. Since its frequency has such a high and constant value that the maximum amplitude the induced voltage is not influenced by the speed of rotation of the disk, one can use one shown in FIG. 3 perform amplitude modulation of this voltage. By Rectification and amplification of this induced voltage can be shown in FIG. 4 signal voltage shown achieve. This signal voltage is then sent to the pulse shaper stage 7 with the transistors 25 and 26 fed, which brings the signal in a rectangular shape. The transistors 41 and 43 of the amplifier 9, like the one in series with the primary winding 11 of the ignition coil 10 Transistor 46 controlled so that the collector current of transistor 46 and thus through the Primary winding 11 current flowing is periodically interrupted. In the secondary winding 49 of the Ignition coil 10, a high voltage is induced in each case, which leads to a discharge at spark plug 50 triggers.

In the contactless ignition arrangement according to the invention is from the coil 3 to the opposite coil 4 high-frequency electromagnetic Transmit energy, the signal voltage is generated by this RF transmission to at certain times by a screen introduced into the space between the two coils rotatable disc is interrupted or at least largely reduced. The advantage here is that the ignition time is not significantly delayed and that the ignition of the internal combustion engine is stabilized State occurs after the voltage generated in the second coil 4 always has a constant signal voltage generated without being influenced by the speed of rotation of the disk 6.

Instead of the constant voltage source 8 (according to FIG. 11), a constant voltage source shown in FIG. 12 can be used in order to present the ignition point electrically in accordance with the speed of the internal combustion engine. This is achieved by connecting the ports a ', V and c' to the ports α, b and c (FIG. 11), while connecting the ports d ', e' and f to the ports d, e and /. Here, the emitter 51 e of a transistor 51 is connected to the collector 38 c of the transistor 38, the collector 51 c via a resistor 52 to the pole B of the DC voltage source. The base 51 b is connected to the collector 26 c of the transistor 26 (output of the circuit 7) and to a diode 54 via a resistor 53. One end of this diode 54 is thus connected to the output of the pulse shaper stage 7, while the other end is connected to the PoIB of the DC voltage source via a variable resistor 55 and the base-emitter path (56 b, 56 e) of a transistor 56. The base 57 and the transistor 57 is connected through a resistor 58 to the collector 51c of transistor 51 is connected, while the emitter 57 is connected directly to the e PoIB the DC voltage source.

The collector 57 c is connected to the cathode of the diode 54 via a resistor 59. A capacitor 60 is connected between the emitter 57 e of the transistor 57 and the cathode of the diode 54. The collector 56 c of the transistor 56 is connected via a resistor 61 and the transistor 38 to the pole A of the DC voltage source and via a variable resistor 62 to the base 63 b of a transistor 63 is connected. Between the emitter 63 e and the

ίο collector 63 c of the transistor 63 is a Zener diode 37. The resistor 34 is between the pole B of the voltage source and the collector 38 c of the transistor 38; a tap is connected to base 36 & of transistor 36. The emitter 36 e of the transistor 36 is connected via the said Zener diode 37 to the collector 38 c of the transistor 38, the emitter of which is connected to the pole .4 of the DC voltage source. The emitter 36 e of the transistor 36 is on the other hand via a resistor 39

ao connected to pole B of the DC voltage source. The collector 36 c of the transistor 36 is connected to the base 38 b of the transistor 38. The output of the pulse monitor stage 7 is directly connected to the connection e ' to which the amplifier 9 is connected.

In the circuit explained above, the output of the pulse shaper stage 7 is at the transistor 51 and the diode 54 connected. When the primary current of the ignition coil 10 is interrupted, the is used Transistor 51 to short-circuit the capacitor 60 via the transistor 57 and the polarity of the Reverse output signal of the pulse shaper 7 for the next charging period.

The capacitor 60 is charged instantaneously via the output of the pulse shaper stage 7 when a current flows through the diode 54 to the primary winding 11 of the ignition coil 10. When the clamping voltage on the capacitor 60 rises and the transistor 56 becomes conductive at a certain base potential, a voltage drop occurs across the resistor 61, so that a base current of the transistor 63 flows through the variable resistor 62 and the transistor 63 becomes conductive. As a result, the Zener diode 37, which serves as a reference voltage source for the constant voltage source 8, is short-circuited, with the result that the potential of the emitter 36 e of the transistor 36 increases, while the collector current, ie the base current of the transistor 38 decreases, which leads to a greater internal resistance and a greater voltage drop in transistor 38.

The pulse amplitude at the output of the pulse shaping stage 7 changes as a function of the speed of the internal combustion engine and is represented by a change in the electrical charge of the capacitor 60 or a change in the terminal voltage of this capacitor. If the capacitor 60 is fully charged, a minimum voltage required for the operation of the device used to determine the ignition point is determined by the output voltage of the constant voltage source 8. If the engine speed increases, the pulse amplitude at the output of the pulse shaper stage 7 decreases, the terminal voltage of the capacitor 60 decreases, the internal resistance of the transistor 63 increases, the potential of the emitter 36 e of the transistor 36 decreases, the collector current increases

309537/134

and the internal resistance of the transistor 38 is reduced, so that a high output voltage of the constant voltage source 8 results.

The waveform of the output signal of the device 1 therefore changes in that of FIG. 8 apparent way; such a change corresponds to an advance of the ignition point. If, for example, the speed of the internal combustion engine increases from WeIIn ₁ to the values n ₂ and n _z , the pulse at the output of the pulse shaper stage 7 becomes narrower, so that the terminal voltage F ₃ on the capacitor 60 and the output voltage F _{4 of} the constant voltage source 8 in the manner shown in FIG. The output voltage F _{1 of} the device 1 and the output signal F _{2 of} the pulse shaper calls 7 change accordingly. The ignition time of the primary current of the ignition coil 10 is shifted accordingly and can be brought forward in this way.

In the arrangement according to the invention, the output signal is used to determine the ignition point serving device by changing the inductively transmitted high-frequency energy by means of

10

the constant voltage source, whose output signal varies according to the speed of the Internal combustion engine changes, so that the output pulses of the pulse shaper stage 7 accordingly the speed can be influenced. These pulses are fed to the ignition coil through an amplifier, which controls the primary current. Since the ignition point is electrically automatic as a function of the speed the internal combustion engine is shifted, the disadvantages that arise with a mechanical Ignition point adjustment result from friction and similar phenomena. The inventive The arrangement is also characterized by a particularly rapid response behavior.

By changing the shape of the lead through the space between the two coils 3 and 4 rotatable disc 6 (see. Fig. 9) you can see the time in which the generated by the coil 3 electromagnetic field is shielded from the second coil 4, affect and on in this way the angular range in which the primary winding 11 of the ignition coil 10 has current flowing through it, change accordingly.

1 sheet of drawings

Claims (3)

1 2 den is. In this air gap runs a metal disk provided with slots, which in turn is connected to rotating parts of the internal combustion engine itself. 1. Contactless ignition arrangement for internal combustion engines and therefore one based on the speed of the internal combustion engine with an ignition coil, the primary engine of which has a matched speed. Development with the ignition energy supplying the size of the air gap between the primary high-frequency oscillator under the control of and secondary coil of the coupling transformer, a single control transformer can be connected, on the one hand and the conductivity of the metal disc on the other Primary coil and secondary coil on the one hand coordinated so that an inductive Has air gap in which an interrupted coupling between the primary and secondary coil of the Metal disk rotates, which the magnetic coupling transformer and thus between the Coupling between the primary coil and the secondary high-frequency generator and the primary winding of the coil of the control transformer and this ignition coil is only given if a contactor the connection between the primary winding of the metal disc in the air gap between primary and the ignition coil and the high-frequency oscillator 15 secondary coil of the coupling transformer is, wähim The rhythm of the internal combustion engine periodically rend this coupling is canceled as long as the establishes and interrupts, thereby marked- metal disc itself within the air gap, that the secondary coil (4) finds the. Overall, the ignition arrangement works so control transformer with the primary winding that the high-frequency generator as a supply source (11) the ignition coil (10) via a pulse shaper 20 for a second oscillator, which in turn, so stage (7) is connected which the current flow through long it the output signal of the high frequency die The primary winding (11) of the ignition coil (10) is fed to the generator, the primary winding of the interrupts and in the secondary winding (49) ignition coil is supplied with power and the generation of the an ignition voltage is induced as soon as its ignition spark is triggered. Such a mode of operation output voltage exceeds a specifiable value, however, is inevitably subject to severe restrictions increases. for the dimensioning of the slots in the 2. Contactless ignition arrangement after the primary and secondary coil of the coupling transformer Claim 1, characterized in that it is connected to the rotating metal disc. These slots The high-frequency oscillator (2) and the pulse shape have to be kept very narrow because merstufe (7) is connected to a voltage source, 30 otherwise an ignition spark occurs for an unnecessarily long time whose output signal in its amplitude of would and possibly even the danger of geder The speed of the internal combustion engine depends on the fact that an ignition spark is then also generated and via the in the secondary coil (4) of the, if the internal combustion engine is at all silent control transformer induced voltage and only the ignition is switched on. Ignition timing determined. 35 On the other hand, the width is too small 3. Contactless ignition arrangement according to the slot in the metal disc insofar as unobjectionable 1 or 2, characterized in that desires, as they to a correspondingly large Abdie Metal disc (6) in its width variable crack angle for the ignition leads, which in turn Contains slots. adversely on the service life of the primary 40 winding of the ignition coil directly connected electronic components. In addition, very small slot widths the time available for the build-up of the high ignition voltage is very short, what The invention relates to a contactless, especially at higher speeds of the combustion Ignition arrangement for internal combustion engines with a 45 engine to an undesirable weakening Ignition coil, the primary winding of which leads to one of the ignition spark energy. Ignition energy supplying high-frequency oscillator and A further ignition arrangement in which the inductive Control by a control transformer, vertical coupling between the secondary winding of the is bindable between the primary coil and the secondary ignition coil and the output of a high-frequency coil has an air gap in which an under- 50 generator by an in adaptation to the ignition breaker Metal disk rotates, which tables revolving the magnetic rhythm of the internal combustion engine The coupling between the primary coil and the secondary slotted metal disc is controlled from the Därspule of the control transformer and about this the German Auslegeschrift 1118 532 known. At the connection between the primary winding of the igniter, the ignition arrangement known to the control coil acts and the high-frequency oscillator used in the rhythm of the inductive coupling the internal combustion engine produces periodically and partial disk directly on the interaction of interrupts. Primary winding and secondary winding of the ignition An ignition arrangement of this type is the subject of a coil. This makes it possible at higher speeds the earlier patent application P 1239886.6. This only very imperfectly, the ignition point exactly Ignition arrangement has a 60 to set on one side. The known ignition arrangement works High-frequency generator with a fixed frequency ar- namely in such a way that the works, and on the other side an ignition coil, necessary high voltage is generated thereby, their primary winding with the high frequency gene that the coupling between the primary winding rator is coupled. The coupling between and the secondary winding of the ignition coil takes place in an adapting between the primary winding of the ignition coil and the 65 solution to the ignition time is interrupted, with High-frequency generator under the control of one the oscillation frequency is determined simply in such a way, Coupling transformer with a primary and a se- that within the ignition time several high-voltage secondary coil, between which an air gap is required. this means