DE2833433A1 - Ignition system for IC engines - measures ignition coil current and closing angle control circuit lengthens interrupter open period accordingly - Google Patents

Abstract

The system has an ignition coil, an interrupter in series with its primary winding, and a battery. A closing angle control circuit is controlled by a pickup synchronously with the engine speed, for the interrupter control. A measurement circuit (22) detects a switching-on signal proportional to the current flowing through the primary winding (16) when the interrupter is closed. This signal is stored, and the closing angle control circuit (12) is controlled by the measurement circuit (22) signal, so that the interrupter (14) opening period is lengthened when the ignition coil current increases.

Description

State of the art

The invention is based on a known ignition device according to the The preamble of claim 1 as described in the company publication "Technical Information" by the applicant with the title "Electronic Battery Ignition Systems", 1st edition, 30. September 1976, pages 9 to 18 is described. In the known ignition device the closing angle control circuit is designed in such a way that the primary circuit is closed from a predetermined upper speed of the engine or the internal combustion engine the interrupter designed as a switching transistor at a fixed predetermined time takes place after the ignition point, the specified point in time being selected so that that there is still a sufficient burning time of the ignition spark on the secondary side the ignition coil results.

In addition, the well-known ignition system is overall dimensioned in such a way that that the residual energy in the ignition coil when the interrupter closes again should have dropped far enough to overload the ignition coil and the switching transistor to prevent. However, the known ignition system does not work in all cases fully satisfactory, since their components are subject to tolerances that are unfavorable Cases can result in the breaker closing too early and thus the occurrence of a relatively large power loss in the switching transistor and in the ignition coil. Nor can this problem be overcome by the breaker is only closed at a later point in time to ensure that it is present to avoid excessive residual energy.

This is because with such an extension of the open time a corresponding shortening of the closing time or

Reducing the closing angle so that the current in the Primary winding can no longer rise to the desired value and consequently not a sufficient one Ignition energy is available.

OBJECT OF THE INVENTION On the basis of the prior art described above the invention is based on the object of providing an ignition device, with the help of which it is possible to determine the time for the closing of the breaker to be regulated in such a way that, on the one hand, the permissible values for the residual energy at the switch-on time are not exceeded and, on the other hand, the presence of a sufficiently high current is guaranteed through the primary winding.

This task is achieved by an ignition device with the features of Claim 1 solved.

Advantages of the Invention In an ignition device according to the invention there is the advantage that impermissible tolerances of the components of the ignition device recognized by an excessively high inrush current when the breaker closes and through a measuring circuit located in a closed control loop can be corrected, in such a way that the open time for the interrupter is just extended by as much that there is still permissible residual energy in the ignition coil at the beginning of the closing time results, while at the same time the still available closing time is optimal can be used.

It is advantageous in an ignition device according to the invention furthermore, that it can be implemented with relatively little effort, if the measuring circuit has a measuring resistor in series with the primary winding, at which, when the breaker closes, one is proportional to the inrush current Voltage jump can be tapped, since such a voltage jump with the help of a Diode-capacitor circuit, which optionally also has one or more resistors contains, can be converted into an inrush current signal in a technically simple manner can, which - if necessary - a correction of the closing time for a can cause subsequent ignition cycle.

It is also advantageous if, in an ignition device according to FIG Invention, the measuring circuit is constructed so that it is proportional to the inrush current Integrated signals, since in this embodiment statistically occurring disturbances can be suppressed by averaging so that they do not affect the can have correct regulation of the closing time.

Drawing Further details and advantages of an ignition device according to the invention will be explained in more detail below in connection with a drawing explained and / or are the subject of subclaims. They show: FIG. 1 a schematic Block diagram of an ignition device according to the invention; Fig. 2a to 2d preferred exemplary embodiments of a measuring circuit for an ignition device according to FIG. 1; 3 shows a schematic circuit diagram of a preferred embodiment an ignition device according to the invention and FIG. 4 is a schematic circuit diagram a further preferred embodiment of an ignition device according to the invention.

Description of the invention examples The basic structure of a Ignition device according to the invention is clear from Fig. 1, where the ignition device is shown in the form of a schematic block diagram.

The ignition device has a transmitter 10, which in the usual way can be designed and is preferably designed as an inductive transmitter. Of the Encoder 10 runs synchronously with the speed of the internal combustion engine for which the ignition device is provided, and generates an output signal in the form of an alternating voltage, whose Frequency of the speed of the internal combustion engine is proportional and that of a closing angle control circuit 12 is fed to an input thereof. The closing angle control circuit 12, which in the usual way, in particular as a Schmitt trigger with variable Switching threshold can be formed, delivers a signal sequence through on the output side which a breaker can be closed and opened in a defined way, wherein the breaker in the embodiment by a switching transistor 14 is formed in series with a primary winding 16 of an ignition coil and to a measuring resistor 18 between the positive pole (+) of a direct current source, in particular a battery, and reference potential is. At the connection point 20 between the emitter of the switching transistor 14 and the measuring resistor 18 is a Measuring circuit 22 connected, the output of which via a line 24 with another Input of the closing angle control circuit 12 is connected.

The ignition device according to FIG. 1 works as follows: When the switching transistor 14, whose collector-emitter path is initially in the conductive state should, by changing the output signal of the closing angle control circuit 12 is blocked, so when the current through the primary winding 16 of the ignition coil is interrupted is, then in the usual way on the secondary side of the ignition coil (not shown) generates an ignition pulse for a spark plug. During this ignition process, the previously Energy stored in the ignition coil is dissipated within a specified time, which is generally shorter than the time up to the point in time at which the now locked switching transistor 14 is again controlled to be conductive.

If, however, the internal combustion engine connected to the ignition device, especially if it is a 6 or 8 cylinder engine, with high speed then it is available for renewed energy storage in the ignition coil standing time so short that it is not possible to wait until the energy in the Ignition coil is completely removed. Rather, the is closed again Interrupter or conductive control of the switching transistor 14 already at a point in time to which still has a certain amount of residual energy in the ignition coil, which results in has that the current through the primary winding 16 when switching on or when switching through of the switching transistor 14 does not rise starting from the value zero, but immediately jumps to a certain inrush current. Such an inrush current can occur at the Dimensioning of the ignition device and is not critical as long as just like the values actually specified when dimensioning the ignition device be respected.

However, due to tolerances, the actual Inrush current is higher than assumed when dimensioning the ignition device became what an inadmissible thermal load of both the switching transistor 14 as well as the ignition coil.

To now the unfavorable effects of excessive inrush currents avoid, the measuring circuit 22 is provided according to the invention, which is on the input side is connected to the measuring resistor 18 and consequently when the switching transistor is switched through 14 detects a voltage jump in the conductive state, the height of which is the same the inrush current in the primary circuit of the ignition device. The measuring circuit 22 is now designed so that they then when the voltage that occurs during the switch-on process jump or the mean value of the voltage jump for several successive ones Switching cycles exceeds a predetermined value, a signal via line 24 supplies to the closing angle control circuit 12, through which the closing time is shortened accordingly during at least one subsequent switching cycle. Since the Ignition time, i.e. the time at which the breaker opens or the Switching transistor 14 is blocked, is fixed, leads to the shortening the Closing time to the fact that the switching transistor 14 compared to an ignition device later controlled into the conductive state without the measuring circuit according to the invention is, namely only at a point in time at which the stored in the ignition coil Energy has already dropped more, so that a correspondingly smaller one and now results in uncritical inrush current.

Overall, with the ignition device according to the invention an optimal distribution of the available time interval over the open time and reach the closing time of the breaker and thus a reduction in the Losses in the ignition coil and in the interrupter to a minimum. The adjustment the switching threshold of the closing angle control circuit as a function of the output signals the measuring circuit on the line 24 can take place in a similar manner to that in those known ignition devices in which a control of the response threshold the closing angle control circuit takes place as a function of the primary current, wherein a voltage drop proportional to this current across a ts measuring resistor 18 corresponding series resistance is determined in the primary circuit.

In FIGS. 2a to 2d there are different embodiments for the measuring circuit 22 of the ignition device according to FIG.

The simplest circuit variant is shown in FIG. 2d, according to which between the input 26 of the measuring circuit and its output 28, as well as in the embodiments according to FIGS. 2a to 2c, the series connection of an input-side Capacitor 30 and a diode 32 is located. A second diode 34 is in the circuit according to FIG. 2d, as well as in the circuits according to FIGS. 2a and 2c, between the Connection point of the input-side capacitor 30 and the diode 32 on the one hand and reference potential on the other. Another or on the output side In all measuring circuits according to FIGS. 2a to d, capacitor 36 is between the output 28 and reference potential.

The circuit according to FIG. 2d works as follows: Every voltage jump Via the measuring resistor 18 or at the input 26 of the measuring circuit 22 passes via the capacitor 30 on the input side to the common connection point of diodes 32 and 34, of which the diode 32 is polarized in such a way that it is used for positive voltage jumps at the input 26 is permeable, while the diode 34 is polarized such that it for negative voltage jumps at input 26 or behind the capacitor on the input side 30 is permeable. The diode 34 results in corresponding negative voltage jumps Signals as they occur when switching transistor 14 is blocked, according to reference potential derived, while positive voltage jumps corresponding signals behind the input-side capacitor 30 from the diode 32 to the output-side capacitor 36 are allowed to pass, so that a corresponding Control signal for the closing angle control circuit 12 is available. The circuit According to FIG. 2d, as shown in FIG. 2c, through an output-side resistor 38 can be added for a defined discharge of the capacitor on the output side 36 provides, but this discharge also, for example, through a transistor (not shown) the closing angle control circuit can take place, its basis is connected to the output 28 of the measuring circuit 22.

Proceeding from the circuit according to FIG. 2c, a corresponding A resistor 40 is also provided parallel to the second diode 34 on the input side which complements the input-side capacitor 30 to form a high-pass filter. In the end starting from the circuit according to FIG. 2a, the second diode 34 can be omitted, when the charging of the input-side capacitor 30 due to a negative Voltage jump across the resistor 40 until the occurrence of the next positive one Voltage jump is sufficiently reduced.

In the ignition device according to FIG. 3, a transmitter 10 is again provided, which controls a Schmitt trigger 42 or a comparable threshold value circuit, the output of which is connected to reference potential via two capacitors 44, 46. The common one Connection point 48 of the two capacitors 44, 46 is on the one hand via a resistor 50 at the positive pole (+) of the direct current source and on the other hand at the base of a Transistor 52, the emitter of which is connected to reference potential via a resistor 54, and its collector via the series connection of two resistors 56,58 with the positive one Pole (+) of the DC power source is connected. The emitter of (npn) transistor 52 is connected to the emitter of a further (pnp) transistor 60, whose collector directly to the reference potential and its emitter via a resistor 62 to the positive Pole (+) of the supply voltage source lies. The base of the further transistor 60 is connected at the output 28 of the measuring circuit 22, which according to FIG.

2a is constructed and its input 26 again with the common connection point 20 of the switching transistor 14 and the measuring resistor 18 is connected. A third Transistor 64 is at the common connection point SZ of the two resistors 56.58 connected.

The ignition device according to FIG. 3 works as follows: The output signals of the Schmitt trigger 42 pass through the capacitor serving as a coupling capacitor 44 to the timer formed from the capacitor 46 and the resistor 50 and determine the open time of the switching transistor 14, i.e. the time in which this switching transistor is in the blocked state, as a blocking time for the transistor 52. This Blocking time is varied in that the transistor 60 depends on the Voltage level at the output 28 of the measuring circuit 22 conducts more or less strongly and thus the voltage across the resistor 54 changes, which is the switching threshold intended for transistor 52. The transistor 64 is always blocked when the transistor 52 conducts and controls, if necessary, via intermediate stages various reasons that are not of further interest here are desirable or necessary can be the switching transistor 14, which is preferably part of a Darlington output stage is.

In the circuit according to FIG. 4, there is again a transmitter on the input side 10 and a Schmitt trigger 42 is provided, the output of which via the coupling capacitor 44 is connected to the timing element 46, 50, but this is in the exemplary embodiment 4 is supplemented by a further resistor 66, which on the one hand connected to node 48 and, on the other hand, to the collector of transistor 60 is. The base of the transistor 60 is connected to the input 28 via a resistor 70 the measuring circuit 22 and also connected via a resistor 68 to the collector this transistor. The collector of the transistor 6u is also again on the Resistor 62 connected to the positive pole (+) of the supply current source. The emitter of In contrast to the exemplary embodiment according to FIG. 3, transistor 52 is direct connected to reference potential and the transistor 52 also leads directly to the Output stage, so that the transistor 64 with its associated resistors 56,58 can be omitted.

The ignition device according to FIG. 4 works as follows: In the ignition device According to FIG. 4, the transistor 60 operates as an inverting amplifier for the voltage at the output 28 of the measuring circuit. The increased voltage on the collector of the transistor 60 takes effect on the series circuit of resistors 50 and 66 of the timer, which at the same time form a base voltage divider for transistor 52. To this This is done in the event of an increased residual energy in the ignition coil or the primary winding 16 of the same at the moment of switching on the switching transistor 14 and at a correspondingly increased voltage jump at the measuring resistor 18 by the then increased Output voltage of the measuring circuit 22, at its output 28 by a corresponding change the course of the base voltage for the transistor 52, the open time for the switching transistor 14 increases that time interval in which this switching transistor 14 is blocked is. Otherwise, the mode of operation of the ignition device according to FIG. 4 corresponds in principle those of the ignition devices according to FIGS. 1 and 3.

Claims (7)

Ignition device for internal combustion engines with a Ignition coil, with a breaker in series with the primary winding of the ignition coil and a direct current source, in particular a battery, and with one by one Encoder synchronously to the speed of the internal combustion engine controllable closing angle control circuit for controlling the interrupter, characterized in that a measuring circuit (22) is provided, with the help of which when the interrupter (14) is closed one proportional to the inrush current then flowing through the primary winding (16) Inrush current signal can be detected and stored, and that the closing angle control circuit (12; 42 to 50; 42 to 66) by the inrush current signal of the measuring circuit (22) in Dependence on the extension that increases with increasing inrush current the open time for the interrupter (14) can be influenced. 2. Ignition device according to claim 1, characterized in that the Measuring circuit (22) has a measuring resistor in series with the primary winding (16) (18), on which, when the interrupter (14) closes, in each case a voltage jump proportional to the inrush current can be tapped. 3. Ignition device according to claim 1 or 2, characterized in that that the measuring circuit (22) integrating devices (36) for forming a dem Average value of the inrush current for several consecutive switch-on processes of the interrupter has proportional inrush current signal. 4. Ignition device according to claim 2 or 3, characterized in that that the measuring circuit (22) is connected between its measuring resistor (18) Input (26) and its with the closing angle control circuit (12; 42 to 50; 42 to 66) connected output (28) the series connection of one with its one connection having a first capacitor (30) connected to the input (26) and a diode (32), those that occur when the interrupter (14) is closed at the measuring resistor (18) Voltage jump is polarized in the forward direction that at the output end of the Diode (32) a storage capacitor (36) is provided, the one facing away from the diode The connection is at the same potential as the input (26) of the measuring circuit (22) facing away from the connection of the measuring resistor (18), and that between the common Connection point of the first capacitor (30) and the diode (32) on the one hand and the point of common potential for the storage capacitor (36) and the measuring resistor (18) a further resistor arrangement (34, 40) is provided. 5. Ignition device according to claim 4, characterized in that that the further resistor arrangement has an ohmic resistor (40) and / or a diode (34), which with respect to their common connection point with the in the series circuit with the first capacitor (30) lying diode (32) opposite is polarized. 6. Ignition device according to claim 4 or 5, characterized in that that parallel to the storage capacitor (36) another ohmic resistor (38) is provided. 7. Ignition device according to one of claims 1 to 6, characterized in that that the output (28) of the measuring circuit (22) with the base of a control transistor (60) of the closing angle control circuit (42, 44 to 66) is connected and that the Interrupter is designed as a switching transistor (14) of a transistor arrangement, their switching threshold as a function of the current through the collector-emitter path of the control transistor (60) is variable.