DE2026028C3 - Capacitor ignition device for internal combustion engines - Google Patents

Description

The main circuit of currently used capacitor igniters already has a constant one Shape. It essentially consists of a storage capacitor charged from a special source, which discharges into the primary winding of the ignition coil via a suitable switching element. As a switching element A controlled semiconductor rectifier is usually used to control the charge of the storage capacitor used, to whose control electrode pulses are passed that depend on the engine speed are that the ignition always takes place at the right moment. The achieved value of tension and energy of the spark, especially at the highest engine speed, where the sparks in rapid succession successive, depends mainly on the type of control of the switching element. It is particular It is important that the switching element locks as soon as possible after the storage capacitor has discharged, d. H. that there is enough time between the individual discharges for a completely new charge of the Storage capacitor remains.

Specifically, an ignition device for internal combustion engines is known (CH-PS 4 78 341) in which a blocking device serving from the control circuit for a main thyristor contains numerous components in addition to an auxiliary thyristor and a Zener diode. This blocking device is not fed directly from the battery, a current pulse for a main control thyristor being generated when the control capacitor is charged and no larger charging current flows after charging.
Furthermore, an ignition device is known (CH-PS 4 48 614), in which a pulse transformer separates the Entladezw <iig from the main control transistor, which is designed as a precision transistor and is therefore very sensitive to changes in operating parameters, such as temperature Components are required, so that this device is also constructed in a complicated manner. It is also known to provide transistors in the ignition device described (DTPS 15 39I91). compared to thyristors, however, aufwei sen the disadvantage that they do not open suddenly like this, but generally gradually. Finally, another ignition device is known (DT-OS 15 39 168), which, however, also has numerous components.

The known capacitor ignition devices have the disadvantage that to achieve a sufficient Charge of the storage capacitor, complicated circuits are used, which are often made up of some semiconductor and other components exist, but this is expensive. On the other hand, appears with a simpler Design of the control circuit a noticeable drop in the voltage and energy of the ignition spark.

It is the object of the present invention to provide a capacitor ignition device of the type mentioned at the beginning Kind to indicate that a reliable function of the capacitor ignition even at the highest required Number of sparks using a single controlled semiconductor rectifier in the control circuit.

This object is achieved according to the invention by the characterizing part of claim 1.

The capacitor ignition device according to the invention is characterized in that it compared to the known devices is constructed more simply with fewer components and even with the highest Spark count enables safe operation.

The invention will now be explained in more detail with the aid of the exemplary embodiments illustrated in the drawing be it shows

F i g. 1 a characteristic curve that indicates how the current from the voltage of the controlled semiconductor rectifier which is suitable for the purposes of the invention, FIG. 2 shows the circuit arrangement of an exemplary embodiment of the capacitor ignition device, in which Control circuit a photothyristor is applied,

3 shows a similar circuit arrangement, but in the control circuit of which a thyristor controlled by electrical pulses is used. In the upper part a

The figure shows an alternative to the circuit of the controlled auxiliary rectifier and a second alternative is indicated in the lower half fc, the components indicated in part b in the second alternative all being indicated within the dashed rectangle in the lower part a of the figure. Replace components and

4 shows an analog circuit arrangement of the capacitor ignition device, in which the control circuit consists of a diode from an independent converter winding is fed. Furthermore, one of the possible ones is in the circuit of the control electrode of the controlled auxiliary rectifier Changes in the circuit of the resistor are indicated, and finally that in FIG. 3 switched Auxiliary capacitor between the anode and cathode of the controlled auxiliary rectifier omitted.

In the diagram according to FIG. 1 shows coordinate axes, the magnitude Be of the voltage Ua being plotted on the abscissa axis, which is fed to the electrode of the controlled auxiliary rectifier, which is indicated schematically at the top left in the figure. The main current h , which flows through the rectifier at a corresponding voltage Ua, is plotted on the ordinate axis. The rectifier diagram also shows the control electrode, which has a similar effect, whether it is a photothyristor controlled by light pulses or a thyristor controlled by electrical pulses.

In the diagram, the value of the holding current Ih of the controlled auxiliary rectifier element is shown in the positive part of the ordinate axis. It follows from the characteristic curve that if no light signal is incident on this element (in the case of a photothyristor) or if no electrical control signal is fed to the control electrode (in the case of a normal thyristor), the controlled auxiliary rectifier always returns to the non-conductive state when whose main current Ia falls below the value In. In other words, if the main current of the controlled auxiliary rectifier is set in such a way that it does not exceed the value Ih , then this element is only open when the corresponding signal is fed to it. This property of the controlled auxiliary rectifier is used to advantage for controlling the ignition instant of the capacitor ignition device according to the invention.

In the circuit diagram of FIG. 2 are shown: a Capacitor 1 of the control circuit, a photothyristor 2 of the control circuit, a Zener diode 3 and a resistor 4 in the circle of the control electrode of the photothyristor 2. We'.ter shows the circuit diagram of resistances 5 and 17 in the control circuit with the photothyristor 2, a distributor 8, a spark gap and a spark plug, respectively 9, a rotating diaphragm 6 and a light source 7. In the ignition circuit there is a storage capacitor 11, an ignition coil 12, a rectifier 13 in the output of the converter 14, contacts 15 of a switch box and a Backup battery 16.

A resistor 18 is connected between the control electrode of the thyristor 10 and the ignition coil 12, as has been found, the function of the thyristor 10 is optimized.

The circuit diagram in FIG. 2 acts in the following way:

The capacitor 1 built into the control circuit is charged from the storage battery 16 via the resistor 17 and the cones 15 of the switch box. The upper voltage level of the capacitor 1 is given by the Zener voltage of the diode 3, which can be omitted in some less demanding cases. At the moment when the photothyristor 2 opens with the corresponding position of the shutter 6, the capacitor 1 discharges through the resistor 5 into the circuit of the control electrode of the thyristor 10 of the ignition circuit, which opens due to the effect of the discharge current of the capacitor 1. The storage capacitor 11 discharges into the primary winding of the ignition coil 12 via the open thyristor 10 of the ignition circuit, and this results in ignition at the corresponding spark plug 9 according to the rotational position of the arm of the distributor 8. The total resistance of the control circuit in which the resistor 17, the Photothyristor 2 and the resistor 5 are connected in series, is chosen so that after the discharge of the capacitor 1 in the circuit of the control electrode of the thyristor 10 no greater current can flow through this circuit than the value of the holding current Ih of the photothyristor 2 corresponds . It follows that after the end of the discharge of the capacitor 1 and after the control pulse, in this case a light pulse, the photothyristor 2 is closed immediately and the capacitor 1 is charged again. The light control pulses for opening the photothyristor 2 come from the light source 7 via the rotating diaphragm 6, which is provided with cutouts 106a and placed on the shaft of the distributor 8.

The mode of operation of the ignition circuit is otherwise known. The storage capacitor 11 is via the Rectifier 13 is charged from converter 14 to a voltage of about 300 V, with the output of the converter is connected to the storage battery 16 via the contacts 15.

The circuit diagram in Fig. 3a and 3b shows a thyristor 102 of the control circuit with a protective capacitor 103 and further the winding of the armature 106 of a Pulse generator 107 and a diode 206 (see FIG. 3 a), which can possibly be a Zener diode, or a diode 306 (see FIG. 3b).

The ignition instant of the capacitor ignition in the circle according to FIG. 3 is controlled in a manner similar to that described in connection with FIG. 2, with the difference that in the control circuit according to FIG. 3, a thyristor 102 is used, which is controlled by electrical pulses generated in the winding of the armature 106 of the generator 107 when its shaft, which is connected to the distributor 8, rotates. The diode 206 (see FIG. 3a), which can also be a Zener diode, or the diode 306 (see FIG. 3b) ensures that the armature 106 reaches the control electrode of the thyristor 102 Pulse always has the correct polarity. The capacitor 103 helps that the thyristor 102 is closed more quickly. As in the case of FIG. 2 is the total resistance of the control circuit according to FIG. 3, in which the resistor 17, the thyristor 102 with the parallel capacitor 103 and the resistor 5 are connected in series, so determined that after the discharge of the capacitor 1 in the circuit of the control electrode of the thyristor 10 through this branch no larger current will flow can than the value of the holding current Ih of the thyristor 102 corresponds. This in turn means that after the discharge from the capacitor 1 has ended and the control pulse from the winding 106 of the generator 107 has subsided, the thyristor 102 is closed immediately and the capacitor 1 is charged again. In comparison with

the function of the control circuit according to FIG. 2 exists in the function of the control circuit according to FIG. 3 no Difference, and the individual components of the control circuit according to FIG. 3 have the same function, like the identically designated components of the control circuit according to FIG. 2.

The circuit diagram in Fig.4a and 4b shows from the Circuit diagram in FIG. 3 the thyristor 102 of the control circuit without protective capacitor and the one in the circuit of Control electrode of the thyristor 102 in series connected resistor 4, which is parallel to the diode 206 (resp. 306) lies. The input of the control circuit is via a diode 20 with a filter capacitor 21 to the independent Winding 19 of the converter 14 is connected. The other components of the control circuit correspond the identically designated components from FIG. 3.

The mode of operation of the control circuit according to the circuit diagram in FIG. 4 is similar to how the Control circuit according to the circuit diagram in Fig. 3. the small difference in the circuit of the resistor 4 in the circuit of the control electrode of the thyristor 102 can under certain conditions favorably in connection with the actual characteristics of the im Express the thyristor used in the control circuit. The supply of the control circuit from an independent winding 19 of the converter 14 represents one of the possibilities for feeding the control circuit. The capacitor 21 moderates the pulsation of the one-way rectified current through the diode 20.

The control circuits according to FIG. 2 to 4, all of which have the same basic idea for the type of control im Apply ignition moment of the capacitor ignition device according to the invention, however, exhaust not all modifications in which the basic idea of the invention described can be exploited. It is Z. B, possible to feed the control circuit from a voltage divider that is parallel to the input of the converter 14 or is connected in parallel to the output of the converter 14 after the rectifier 13, or this voltage divider can be replaced by a suitable series resistor. Likewise can also the control circuit can be fed via an independent rectifier, which comes from a tap or a independent winding of the converter 14 fed v. earth. However, there are also other options for this Art.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Capacitor ignition device for internal combustion engines, with an ignition circuit having a storage capacitor and a controlled rectifier and with a control circuit connected to the control electrode of the controlled rectifier, which has a control capacitor connected to ground, a controlled auxiliary rectifier, a first and a contains a second series resistor and is formed from a charging and a discharging branch for the control capacitor, the ignition circuit and control circuit being fed from a common power source, characterized in that the charging branch consists only of the first series resistor (17) between the power source and the other Connection of the control capacitor (1) is so that the discharge branch consists only of the controlled auxiliary rectifier (2, 102) and the second series resistor (5), the anode of the controlled auxiliary rectifier (2, 102) at the other connection of the control capacitor ( 1) and its cathode is connected to the control electrode of the controlled rectifier (10) via the second series resistor, and that the two series resistors (5, 17) have such resistance values that after the discharge of the control capacitor (1) via the discharge branch the through the controlled auxiliary rectifier (2,102) is less than the holding current (Ih) of the controlled auxiliary rectifier (2,102). 2. Capacitor ignition device according to claim 1, characterized in that in parallel with the control capacitor (1) a zener diode (3) is connected. 3. capacitor ignition device according to claim 1 or 2, characterized in that the controller of the auxiliary rectifier (2, 102) is carried out by light pulses, which by interruption of one of a light source (7) emitted light beam with the aid of a rotatable, between light source (7) and Auxiliary rectifier (2, 102) arranged aperture (6), which has regularly distributed translucent and opaque areas are generated. 4. capacitor ignition device according to claim 1 or 2, characterized in that the controller of the auxiliary rectifier (2. 102) is carried out by electrical impulses from a dynamoelectric Pulse generator (107) are generated.