DE1239886B - Ignition circuit for internal combustion engines - Google Patents

Description

Zündschaltuna for Brennkraftinaschinen C The invention relates to an electronic Zündschaltuno in, for internal combustion engines.

Ignition devices for internal combustion engines have become known that hold a trigger circuit ent-Z, 9, which controls the generation of the ignition sparks and in which a magnetic device is also provided which is driven by the motor and which controls the trigger circuit (German Auslegeschrift 1099 268) .

It is also known to use an oscillator in an ignition circuit (British patent 808714).

However, these known circuits are useless in practice and never came to fruition.

Furthermore, an electronic ignition circuit for internal combustion engines has become known (French patent 1155 541) in which a magnetic control circuit operates an oscillator which is directly connected to a spark generator. This known arrangement provides a very large number of sparks to each spark plug, which in practice is very unfavorable.

The invention relates to an electronic ignition circuit for Internal combustion engines with a Trig circuit, which is controlled by a Magnetsteuerereinricheg device is controlled, which is driven by the engine. According to the invention, a per se known oscillator arranged, which under control by means of a magnet control device, supplies pulses to the trigger circuit and a pick-up winding for coupling the Oscillator is provided to the trigger circuit, which is based on the frequency of the oscillator is matched.

It was only through this arrangement that it was possible to find a really useful one To create ignition circuit for internal combustion engines on an electronic basis.

The present invention is to be explained in more detail below on the basis of exemplary embodiments and with reference to the drawings. In these, FIG. 1 is a circuit diagram illustrating an embodiment of the present invention, FIG. 2 and 3 corresponding sketches at right angles to one another, which represent the magnetic device for controlling the oscillator, F i g. Fig. 4 is a side section showing a practical arrangement of the magnetic means for controlling the oscillator and combined with a conventional motor distributor, Fig. 5 shows a side section from FIG. 4, fig. 6 is a sketch similar to FIG. 3, showing a modified embodiment of the present invention, FIG. 7 shows a sketch similar to FIG. 3, which shows a further exemplary embodiment, FIG . 8 is a diagram showing a partial circuit according to FIG . 7 represents, FIG. 9 shows a further change for part of the circuit shown in FIG. 1 is shown, FIG. 10 a change from FIG. 8, Fig. 11 and 12 are sketches showing the corresponding changes to the arrangement shown in FIG. 7 is shown, FIG. 13 shows a practical embodiment of F i 11, Fi-. 14 is a circuit diagram showing a modified version Z of FIG. 1 shows and F i 15 shows a change in F i -. 1, which is also applicable to the other circuit diagrams. Referring to FIG. 1 , a first and a second terminal 21, 22 are provided here, which during operation are connected to a battery or to another direct current source 23 and in this way have a corresponding positive and negative polarity. Furthermore, a first transformer 24 is provided, in which one end of the primary winding 25 is connected to the terminal 21 and the other end of its primary winding 25 is connected to the collector of an npn transistor 26 . The emitter of this transistor 26 is connected to the terminal 22 via a resistor 27 , while one end of its base is connected to the secondary winding 28 of the transformer and the other end is connected to the terminal 21 via a resistor 29 ; the resistor 29 is bridged by a capacitor 31.

A transformer 32 is also provided, in which one end of the primary winding 33 is connected to the terminal 21 via a resistor 34 and the other end of the winding 33 is connected to the collector of an npn transistor 35 , the emitter of which is connected to the terminal 22 is. The base of the transistor 35 is connected to the emitter of the transistor 26 via the secondary winding 36 of the transformer 32 .

The collector of the transistor 35 is connected to the cathode of a diode 37 , the anode of which is connected to the terminal 21 via a resistor 38 . In addition, the anode of the diode 37 is connected in series to the base of an npn transistor 42 via the anode and cathode of diodes 39, 41. The base of the transistor 42 is also connected to the terminal 22 via a resistor 43, while the emitter is connected to the terminal 22 and its collector to the terminal 21 via the primary winding 44 of an ignition transformer 45.

The secondary winding 46 of the ignition transformer 45 is connected in sequence to the spark plugs 48 of the engine via a distributor 47 which is driven by the engine.

The transformers 32, 45 are arranged around none in such a way that their windings are permanently magnetically coupled. Meanwhile, the magnetic circuit of the transformer 24, as shown in FIG. 2 and 3 , an open rectangular groove 49 which is interrupted along one of its long sides. The turns 25, 28 are wound around the legs on the ent-e-en-esetzt sides of the gap around the no-wound. The arrangement is such that the air gap between the turns is large enough to effect a magnetic coupling. A disk 51 is rotatably mounted about an axis which is arranged parallel to one of the long sides of the core and is driven by the motor to which this ignition circuit is connected at the speed of the engine and at a speed dependent on it . Conveniently, the disk 51 is driven by the distributor shaft. The disk includes four slots 52 which extend inwardly from the circumference towards the center of the disk and which are alternately arranged at right angles to one another. The disc is driven in such a way that it revolves between the windings 25, 28 , and the arrangement is such that only when a slot 52 is brought into correspondence with the two parts of the interrupted leg around which the windings are wound C, C is that the windings are then magnetically coupled. At the other times, the turns 25, 28 are not magnetically coupled. The disc described can be used for an engine with four cylinders, and in all other cases the number of slots must be chosen equal to the number of cylinders. In addition, the disk 21 can also be driven indirectly by the motor via a transmission or reduction gear. In this case, the number of slots must be either a fraction or a multiple of the number of cylinders.

The disk 51 is made of conductive material and the arrangement is such that when a fixed portion of the disk is between the turns of the transformer 24, the eddy currents of such magnitude flowing in the disk cause vibrations of the circuit containing the transformer 24 and the transistor 26 are interrupted. A small current flows through the collector and emitter of transistor 26, but transistor 35 is not conductive. In addition, the current which flows through the resistor 38 and the diodes 39, 41 in series, keeps the transistor 42 in the conductive state, so that a current flows through the primary winding 44 of the ignition transformer 45.

When one of the slots 52 appears between the windings 25 , 28, the circuit which contains the transformer 24, the resistor 29, the capacitor 28 and the transistor 26 begins to oscillate in a known manner, so that an alternating voltage is generated across the resistor 27 will. The first effect of this voltage causes the transistor 35 to be placed in the conductive state. When the transistor 35 conducts, a current can flow through the resistor 38 via the diodes 37 and the collector and emitter of the transistor 35 , so that the transistor 42 is switched off. Turning off the transistor 42 has the effect that a high voltage is generated in the secondary winding 46 of the ignition transformer and a spark is generated at one of the spark plugs 48.

The transformer 32 has the effect that the current in the transistor 35 is reduced by the feedback effect between its collector and base until saturation is reached. At this point transistor 35 is turned off and transistor 42 is turned on again. At this point in time, if transistor 26 and its associated components are still oscillating, another spark will be generated. Therefore, at speeds below a predetermined value, more than one spark will be applied to each spark plug. Meanwhile, if by the time transistor 35 is non-conductive, transistor 26 and its associated components have stopped oscillating, only a single spark will be applied to each spark plug 48.

The F i g. 2 and 3 schematically show the mechanical control device which controls the oscillator. In the F i g. 4 and 5 , however, a practical arrangement is shown which is combined with a conventional distributor in place of the normal contact breaker. With reference to FIGS. 4 and 5 , a housing 53 is provided here, within which a shaft 54 is rotatably arranged, which is driven by the motor. A part of the shaft within the housing is surrounded by a sleeve 55 and is firmly connected to it. The sleeve 55 has an enlarging cross section at one end and is in driving engagement with an isolation member 56 which carries a rotary lever 57 which extends radially to the shaft 54. At its inner end the rotary lever 57 is in contact with a plug 58 which is connected to the winding 46 of the ignition transformer 45 and at its outer end this lever ends in a conventional manner, in a curved part extending around the circumference (in F i g. 4 CC in not shown), which is brought into contact with four contact pieces 59 when the shaft rotates, which are connected to the spark plugs 48 of the engine so that the current can flow through the rotary lever 57 to the spark plugs 48 .

A plate 61 is attached to the housing 53 which, as shown in FIG. 5 , extends around a portion of the C el gt shaft 54. The plate 61 carries a pin 62 -, a joint is on the pivotally and rotatably disposed at an angle, which carries a pair of C arms 63,64 which extend arcuately against set to ent-C C sides of the shaft 54th The arm 63 carries at its end a housing 65 in which the core 49 of the oscillator is arranged. The disc 51 is replaced by a drum 66 which is mounted on the sleeve 55 so that it can be rotated together with the sleeve. The drum 66 is slotted so that when a slit passes between the interrupted legs of the core 49, energy is delivered to the rotary lever 57 by the ignition transformer. The drum 66 is arranged opposite the rotor shaft so that the rotary arm is always in electrical communication with a spark plug 48 when the oscillator is actuated.

On the housing 53 terminals 67 are arranged in the housing and it is un a provision for accommoda-, - made by lines C, C that extend between the terminals 67 and the Windunggen on the core 49th Three clamps are required to make the necessary connections to the turns 25, 28. The end of the turn 25 which is connected to the terminal 21 is grounded in a suitable manner. In order to accommodate the leads extending between clamps 67 and turns 25 and 28, arm 63 is slotted to receive these leads and a C part 68 is attached to plate 61 to thereby define a clamp. through which the lines extend.

A standard mechanism 69 is provided for centrifugal advancement of the sleeve 55 and the isolation member 56 through an angle. Further control of the timing is provided by a known mechanism 71 which is responsive to the pressure in the intake manifold of the engine. This mechanism controls the angular position of the arms 63,64. Although the arm 63 moves an angle about the bolt 62 and the drum 66 moves an angle about the shaft 54, sufficient clearance is provided for the mechanism to operate satisfactorily.

If desired, the air gap can have such a dimension that no oscillations can arise. In this case, as shown in FIG. 6 , the core 49 may be U-shaped C and the disc 51 is replaced by a turnstile containing four magnetic arms 72 . The vibrations can therefore only arise if such a magnetic arm is located above the legs on which the windings 25, 28 are wound.

F i g. 7 shows a modified embodiment in which the turns 25, 28 are wound around the same leg of the core 49 so that they always oscillate, the oscillating circuit being connected to the rest of the circuit only when it is necessary to generate a spark . For this purpose, the other leg of the core carries a winding 70 which is connected to the resonant circuit either through a slotted disc 51, as in FIG. 2, or by a turnstile having arms 72 as shown in FIG. 7 is coupled. The circuit for this embodiment is in comparison with FIG. 1, as it is in F i c-. 8 is modified. As in Fig. 8 , the resistor 27 and the connection of the emitter of the transistor 26 with the winding 36 are omitted here. The emitter of transistor 26 is directly connected to the terminal 22, and moreover, the resistor 29 and the capacitor 31 is designed in parallel between the Winduno, 28 and the base of transistor 26 C, instead of between the winding 28 and the terminal 21. The One end of winding 70 is connected to terminal 22 and its other end is connected to the base of transistor 35 via winding 36 .

In a modified embodiment of FIG . 1, shown in FIG. 9 , the transistor 26 is replaced by a pnp transistor 73 . In this case, the emitter of the transistor 73 is connected to the terminal 21 and its collector is connected to the terminal 22 via a resistor 74 in series with the winding 25 . The base of the transistor 73 is connected to the terminal 22 via the resistor 29 in series with the winding 28, the resistor 29 , which is bridged by a capacitor 31 as before. A point between the resistor 74 and the winding base 25 is connected to the base of the transistor 35 via the winduno 36 . This circuit, which is carried out in the same manner as in FIG. 1 is particularly useful when the negative terminal of power source 23 is grounded.

The circuit shown in FIG. 8 , it can also be modified so that a pnp transistor can be used in place of transistor 26. in F i c-. 10 shows such a pnp transistor 75 Cre, the base of which is connected to the terminal 22; in this case the emitter of the transistor 75 is connected to the terminal 21 via the winduno, 28 and the parallel connection of the resistor 29 and the capacitor 31. The primary winding 25 is connected between the collector of the transistor 75 and the terminal 21. The operation is the same as that of the circuit shown in FIG. 8 Cledex C, gt is.

The arrangement shown in FIGS. 7, 8 and 10 is Darge a. is not entirely satisfactory because it is difficult to make a satisfactory oscillator on one leg of a core, and moreover, there is some loss between the oscillator turns and the tap turn. To overcome these difficulties, the oscillator windings are removed from No 49. The tap turn 70 is wound around one leg of the core 49 as before, and the output from the oscillator is passed through two additional turns connected in series with one another and with the winduna, 25 , with the additional turns wound around the none 49 are. Magnetic control means is provided, as before, and the arrangement and dimensions of the additional turns are such that, when a spark is not required, the voltages created in the tap turn 70 are canceled by the additional turns. However, when a spark is required, this balance is broken by the magnetic device.

Numerous arrangements are possible, but in one embodiment shown in FIG. 11 , the core 49 is E-shaped, with a pick-off coil 77 wound on its middle limb and the additional turns 76, 77, which are connected in series, on the outer limb. A magnetic arm 72, driven by the motor, slides over the centralmost leg and one of the outer legs to unbalance when a spark is required. In the exemplary embodiment shown in FIG. 12, a two-legged pin 49 is provided with the turns 76 on one leg and the other turns 77 and the ripening winduno 70 on the other leg. The additional turns 76, 77 are not the same in this case. The equilibrium is canceled by a magnetic arm 72 which guides over the two legs.

The ma-netic material used for the cores and arms must have negligible eddy current losses and low magnetic reluctance exhibit; soft ferrites were found to be suitable for this.

A further improvement can be obtained by tuning the pickup coil 70 to the oscillator frequency. In addition, although in the examples described the output from the oscillator is applied to two additional turns connected in series, such an effect can be achieved by applying the oscillator output over a single turn, with two tapping connections that are oppositely coupled, to be used.

The circuit shown in FIG. 11 is difficult to tune due to manufacturing tolerances, and therefore the arrangement shown in FIG. 13 is preferred. This arrangement c: ZD 3 can be combined with a conventional distributor and contains the core 49 which is carried by a housing 121 which is fixed on a non-rotatable part 122 of the distributor. The core carries the windings 70, 76, 77 and the arms 72 are formed by ferrite rods 123 carried by a part 124 which is rotatable with the distributor shaft. No 49 is deliberately not tuned, and an exact tuning is achieved by means of an adjustable ferrite rod 125 which is carried by the housing 121 and can be moved against or by the leg that carries the winding 76.

In all circuit diagrams that have been described so far, two blocking oscillators have been used. The first oscillator, which contains the transistor 26 ( Figs. 1 and 8) or 73 (Fig. 9) or 75 ( Fig. 10) , is operated by a magnetic control device which is driven by the motor, and in turn actuates the second oscillator, which in any case contains the transistor 35 and generates a signal to the ignition transformer 45. The circuit which will now be described is a modification of FIG. 1, in which only a single transistor is used for both blocking oscillators. Referring to FIG. 14, a first and a second terminal 81, 82 are provided here, which are connected to a direct current source in such a way that they have a positive and a negative polarity, respectively. The terminal 81 is connected in parallel to one end of a secondary winding 85 of a first transformer 86 via a resistor 83 and a capacitor 84, this winding 85 being bridged by a resistor 87. A variable point on the resistor 87 is connected via the anode and cathode of a diode 88 to the base of an npn transistor 89 , the emitter of which is connected to the terminal 82 and the base of which is connected to the terminal 82 via a resistor 91 and its collector is connected to the terminal 82 via the cathode and anode of a Zener diode 92 .

The collector of the transistor 89 is also connected to the terminal 81 via the primary winding 93 of a second transformer 94, the winding 93 being bridged by a series circuit which contains a resistor 95 and the primary winding 96 of the transformer 86 . One end of the secondary winding 97 of the transformer 94 is connected to the terminal 82 and the other end is connected to the base of the transistor 89 via the anode and cathode of a diode 98 .

The circuit also contains an npn transistor 99, the emitter of which is connected to the terminal 82 and the base of which is connected to the terminal 82 via a resistor 101 . The base is also connected via the cathode and anode of a diode 102 to the cathode of a diode 103 , the anode of which is connected to the terminal 81 via a resistor 104 and to the collector of the transistor 89 via the anode and cathode of a diode 105 . The collector of the transistor 99 is connected to the terminal 81 via a resistor 106 in series with the primary winding 107 of an ignition transformer 108 , the secondary winding 109 of which can be connected in sequence to the spark plugs of the engine via the distributor (not shown) during operation.

As before, magnetic means driven by the motor serve to couple windings 85,96 when a spark is required to allow the flyback oscillator formed by transformer 86 and transistor 89 to be established , is vibrated due to the effect of the feedback between the collector and base of transistor 89 - through transformer 94. The values of the circuit are such that these vibrations do not saturate transistor 89 and so, although part of the current , which flows through the resistor 104, is diverted via the transistor 89 , sufficient current flows via the base and the emitter of the transistor 99 to keep it in the conductive state.

At a predetermined amplitude, the oscillations in transformer 86 actuate the blocking oscillator formed by transformer 94 and transistor 89 , the arrangement being such that transistor 89 becomes saturated and so the base-emitter circuit of the transistor 99 shorts. The drop in the flux in ignition transformer 108 now creates a spark on a spark plug. At low speeds, the transformer 86 may still be magnetically coupled after a spark is created, in which case more than one spark can be applied to each spark plug.

In all of the exemplary embodiments described so far, a transistor 42 or 99 is connected in series with the primary winding of the ignition transformer. However, this transistor can also be replaced by a switchable rectifier. The switchable rectifier is a device which is similar to a controlled rectifier, but has an additional property that it can be switched off by a pulse which is applied to its control electrode. The use of a switchable rectifier simplifies the circuit, since the only required connection between the second transformer 32 or 94 and the switchable rectifier is an additional turn on the second transformer, one end of which to the negative terminal and the other end to the control electrode of the switchable Rectifier is connected. The F i g. 15 shows the arrangement as in FIG. 1. One end of the additional winding 111 is connected to the terminal 22 and the other end of which is connected to the control electrode of the switchable rectifier 112; the cathode of the switchable rectifier 112 is connected to the terminal 22 and its anode is connected to the winding 44 via a resistor 113 . A negative pulse is applied to the control electrode when transistor 35 is in the conductive state and a positive pulse is applied to the control electrode when the voltages in the transformer windings of transformer 32 are reversed as a result of transistor 35 saturating. The reverse voltage on the windings is preferably limited by a resistor and diode (not shown) connected in series with winding 33 .

Claims (2)

Claims: 1. Electronic ignition circuit for internal combustion engines with a trigger circuit which 0 t) 3 is controlled by a magnetic control device which is driven by the motor, characterized in that a known oscillator is arranged, which sends pulses to the trigger circuit under control a magnet control device and a tapping winding (70) is provided for coupling the oscillator to the TrigtaDerschaltung, which is tuned to the frequency of the oscillator. 2. Ignition circuit according to claim 1, characterized in that the oscillator is constantly connected to the trigger circuit and the magnet control device is switched such that the oscillations of the oscillator are only released when an ignition spark is required. 3. Ignition circuit according to spoke 1, characterized in that the oscillator is operated continuously and the Magnetsteuerebnichtung is switched such that it separates the oscillator from the trigger circuit with the exception of the times at which an ignition spark is required-4. Ignition circuit according to one of Claims 1 to 3, characterized in that the oscillator is a blocking oscillator which consists of a transistor (26 or 73 or 75) with transformer windings (45) which are connected in the base-collector circuit of this transistor to form part of this oscillator. 5. Ignition circuit according to spoke 4, characterized in that the trigger circuit is formed by a second blocking oscillator which contains a transformer (45) whose turns are connected in the collector-base circuit of a transistor (35) . 6. Ignition circuit according to claim 4 or 5, characterized in that a common transistor (89) is provided in both blocking oscillators and the arrangement is such that the first blocking oscillator alone cannot saturate the transistor (89) , but the transistor is saturated, when the second blocking oscillator comes into action. 7. ignition circuit according to claim 1, characterized in that a conventional distributor forms part of the ignition circuit and the magnetic control device is arranged in the distributor and is driven by the shaft of the distributor. Documents considered: German Auslegeschrift No. 1099 268; German utility model No. 1786 244; French Patent No. 1155 541; British Patent No. 808,714. USA.- Pat. No. 2,875,744.