DE2821062A1 - Ignition system for IC engine - has interrupter controlled by output of threshold switch, itself controlled by signal generator - Google Patents

Abstract

The system (1) has an interrupter which is connected in series with a battery and a primary winding of an ignition coil. The interrupter relative conducting period is varied by the output signal of a threshold switch in accordance with the engine speed. The control signal of an inductive signal generator synchronised with the engine is applied to the switch. Its switching threshold is varied by a control voltage. The control voltage varies in accordance with the control signal period duration.

Description

State of the art

The invention is based on an ignition device as it is according to the The preamble of claim 1 is assumed to be known. In the known ignition device (DE-OS 25 49 586) the control voltage is generated depending on the point in time to which the current flows through the primary winding of the ignition coil after closing of the interrupter or after switching through the electronic interrupter in In the form of a Darlington transistor circuit, a predetermined maximum value has been reached.

In particular begins with the known ignition device after reaching of the maximum value of the primary current, the charging of a capacitor from a constant current source except for a peak value at the time the breaker was opened or

of blocking the Darlington pair. At this point begins a defined discharge of the capacitor via another constant current source. The voltage across the capacitor is used as a control voltage at an input of the threshold switch effective and determines its switching threshold for switching depending on the encoder signal in such a way that the closing time for the interrupter is shortened, if the maximum allowable current through the primary winding is already more or less is reached early before the end of the closing time.

In this way, with the known ignition device electronic A closing time regulation has been achieved that enables complicated and expensive special forms for the encoder to obtain an alternating voltage special To dispense with the waveform at the output of the same. It is disadvantageous in the known Ignition device, however, that it is not readily possible to one side of the To ground the coil of the encoder, over which the control voltage is generated and that also a considerable complexity in terms of circuitry with a large number of discrete semiconductor components is required, which the known ignition device is relatively expensive and prone to failure power.

Similar problems arise with another from DE-AS 2 124 310 known ignition system for internal combustion engines, in which the switching threshold for a transistor to regulate the closing angle also as a function is varied from the point in time at which the maximum value of the primary current within the closing time is reached.

OBJECT OF THE INVENTION On the basis of the prior art and the above The problems identified, the object of the invention is to provide an improved Specify ignition device with the possibility of using the transmitter on one side to ground, in which also the closing angle control circuit and the associated control devices can be combined in an integrated circuit and in addition there is the possibility of using at least one selected operating parameter the ignition device equipped internal combustion engine in the regulation of the relative To take into account the closing angle.

According to the invention, this object is achieved by an ignition device solved with the features of claim 1.

Advantages of the Invention The ignition device according to the invention offers the decisive advantage that there is no special one for obtaining the control voltage Signal form of the signal generator and no circuits to be precisely matched Control voltage generation are required, which may have a special Have temperature compensation; instead, the control voltage becomes the control the closing angle depending on the period or the frequency of the Control signal of the signal generator obtained, the frequency of the control signal Is a parameter that can practically not be influenced by any disturbances and can be evaluated extremely easily, especially if you are working on the Invention uses a frequency-voltage converter, which preferably consists of a few Diodes, resistors and capacitors is constructed.

Furthermore, the invention offers the possibility of using the encoder or

the coil of the encoder, via which the control signal is generated, on one side to ground, which has the advantage of defined potential ratios at the encoder coil and facilitates the construction and connection of the encoder.

It is particularly advantageous in the case of an ignition device according to FIG Invention further that with the exception of the encoder and the output stage, i.e. the electronic Interrupter, all circuit parts combined into an integrated circuit can be used in the large series customary in motor vehicle construction comparatively can be manufactured cheaply and with high reliability.

DRAWING Further details and advantages of the invention are provided below in connection with preferred embodiments based on a drawing explained in more detail and / or are the subject of the subclaims. They show: Fig. 1 a Basic circuit diagram of the essential parts of an ignition device according to the invention; 2 shows a circuit diagram of a preferred embodiment of a frequency-to-voltage converter the ignition device according to FIG. 1; and FIGS. 3 to 6 show a basic circuit diagram or partial circuit diagrams modified embodiments of ignition devices according to the invention with the Possibility of influencing the control voltage through at least one operating parameter an internal combustion engine equipped with the ignition device.

Description of the examples of the invention In the ignition device according to Fig. 1, a transmitter 10 is provided on the input side, which in the usual way, in particular as inductive transmitter, which is similar to an interrupter in a conventional ignition system with the speed of the one equipped with the ignition device Internal combustion engine is synchronized. The encoder 10 has a coil 12, which is unilateral is grounded and the other end is connected to a node 14 where a periodic control signal in the form of an alternating voltage can be tapped, which Amplitude changes with the speed of the internal combustion engine and its shape in is generally also speed-dependent.

The node 14 is via a resistor 16 to the inverting Input (-) of a first operational amplifier 18 connected. With the inverting The input of the first operational amplifier 18 is also the tap of a voltage divider from two resistors 20,22 connected between battery voltage UB and reference potential lies. The battery voltage UB also serves as the supply voltage for the first operational amplifier 18, as indicated in the usual way. The exit 24 of the operational amplifier 18 is on the one hand with the control input of an electronic Interrupter, in particular in the form of a Darlington transistor circuit, connected. The interrupter (not shown) forms the final stage of that shown in FIG Circuit. The output 24 of the first operational amplifier 18 is also via a Feedback resistor 26 to the non-inverting input (+) of the first operational amplifier 18 connected, with this non-inverting input at the same time the output a frequency-to-voltage converter 28 is connected via a resistor 20. The circuit point 14 at the output of the encoder 10 is also via a resistor 32 to the non-inverting input (+) of a second operational amplifier 34 connected which in turn the battery voltage UB as the supply voltage fed will. The second operational amplifier 34 is with its inverting input (-) connected to the tap of a voltage divider consisting of two resistors 36,38, which lie between the battery voltage UB and the reference potential. Another resistance 40 lies between the battery voltage UB and the non-inverting input (+) of the second operational amplifier 34, 'whose output 42 is connected to the input of the frequency-voltage converter 28 is connected.

Fig. 2 of the drawing shows that the frequency-to-voltage converter is very can be easily constructed. In detail, at the input of the converter 28 or at the output 42 of the second operational amplifier 34 one plate of a capacitor 44, the other plate of which is connected to the anode of a first diode 46, whose Cathode is at reference potential and at the cathode of a second diode 48. The The anode of the second diode 48 is connected to the output 52 of the converter via a resistor 50 28 connected with a second capacitor between the output 52 and reference potential 54 is located. It is also the connection point of the second diode.48 with the resistor 50 connected to reference potential via a further resistor 56.

The ignition device according to FIGS. 1 and 2 works as follows: The first Operational amplifier 18 serves as a threshold switch and is inverting at its Input (-) through the control signal of the encoder 10 at the switching point 14 via the Resistor 16 controlled, the voltage at the inverting input of the first Operational amplifier 18 through the voltage divider 20, 22 simultaneously through the Battery voltage UB is influenced.

A correction is therefore made with the aid of the voltage divider 20, 22 the Switching threshold of the first operational amplifier 18 to compensate for fluctuations its supply voltage, which is also formed by the battery voltage UB or is derived from this. The periodic voltage changes at the output 24 of the first Operational amplifier 18, which the open time and the closing time of the output stage determine, change, as is usual with threshold switches in ignition devices, as a function of the speed of the internal combustion engine, the speed information, as far as the first operational amplifier 18 is concerned, on the dependence of the amplitude of the control signal at node 14 is based on the speed. The second operational amplifier 34 is connected to its non-inverting input (+) via resistor 32 as well applied to the AC voltage control signal at node 14.

Its output signal U2 at output 42 is, as indicated in Fig. 2, a square pulse train in which the timing of the pulse edges depends on the voltage at the tap of the voltage divider 36,38 or at the inverting input (-) of the second Operational amplifier 34 is determined, with the help of resistor 40 in a similar way Way as described for the first operational amplifier 18 again is achieved that changes in the battery voltage UB in their influence on the Output voltage U2 can be compensated. In addition, the switching thresholds of the second operational amplifier 34 selected so that the amplitude curve of the control signal at the circuit point 14 no or only a negligibly small influence whose output voltage U2 has, so that the square pulse train U2 at the input of the Converter 28 represents pure frequency information. Depending on the frequency of the square pulse train U2 at the output 42 of the second operational amplifier 34 results from the output side Capacitor 54 of converter 28 a higher or lower voltage, which the voltage at the non-inverting input (+) of the first operational amplifier 18 and thus its switching thresholds in the desired Way influenced. From the above description it is clear that the frequency-to-voltage converter 28 can also be designed in a different way than according to FIG. 2, in order to be frequency-dependent Generate voltage, the relationship between frequency and voltage being linear or can be nonlinear.

In the ignition device according to FIGS. 1 and 2, all components or circuits which are within the block 58 shown in dashed lines, can be combined into a single integrated circuit.

The ignition device according to FIG. 3 is opposite to that according to FIG Fig. 1 and 2 added, wherein in detail a measuring resistor 60, a sampling and Holding circuit 62, a memory in the form of a capacitor 64 and a control amplifier 66 are provided, the two inputs of which are preceded by resistors 68 and 70, respectively whose output is fed back to its input via a resistor 72 and its output further via a resistor 74 to the inverting input (-) of the first operational amplifier 18 is connected.

The measuring resistor 60 is in series with the primary winding 76 of a Ignition coil and to an output stage transistor 78 between the battery voltage UB and Reference potential and is via a signal line 80 to a first input of the Sample and hold circuit 62 connected. A second input of this circuit 62 is connected to a control line 82, during the Output of the Circuit 62 via the capacitor 64 to reference potential and via the resistor 68 is at the non-inverting input (+) of the control amplifier 66.

The ignition device according to FIG. 3 works as follows: In the ignition device 1 and 2 it can happen that the current through the primary winding of the Ignition coil at the point of ignition due to tolerances of the sender 10 and adjustment tolerances of the circuits forming block 58 at the time of ignition, i.e. when the electronic Interrupter (when switching through the output stage transistors) deviates from the setpoint.

In the ignition device according to FIG. 3, the current now leads through the Primary winding 76 to a corresponding voltage drop across the measuring resistor 60. This voltage drop is transmitted via the signal line 60 to one input of the Sample and hold circuit 62 supplied, which upon arrival of a lock signal for the output stage transistor 78 from the output of the first operational amplifier 18 via their control line 82 in a known manner, not to be described here in more detail, for a short time is opened, so that the voltage across the measuring resistor 60 is immediately before the blocking of the output stage transistor 78 is taken over by the capacitor 64 and then can be held because the circuit 62 blocks again immediately. The tension on Capacitor 64 is connected to the non-inverting input (+) of the resistor 68 Control amplifier 66 effective as a reference voltage, which is connected to a voltage at the inverting Input (-) of the control amplifier 66 is to be compared, this voltage being a Represents a setpoint or a reference variable, that of an operating parameter the internal combustion engine equipped with the ignition device is dependent.

The ignition device according to FIG. 3 is made possible by recording and storing a voltage corresponding to the cut-off current a correction of the closing time or the relative closing angle in the sense that the closing time increases with Actual value of the shutdown current is shortened and vice versa. This is used for the correction the closing time does not require a control arrangement such as a control transistor, but only one switching arrangement, in particular a switching transistor, which also changes the parameters of the circuit, for example due to aging phenomena and the like are regulated.

Furthermore, the ignition device according to FIG. 3 enables by applying a corresponding voltage at node 76 on the control amplifier 66 facing away from the side of the resistor 70 a sudden changeover of the switching thresholds of the first operational amplifier 18. Such a sudden changeover of the Switching thresholds of the first operational amplifier 18 as a function of vehicle and / or EIotorparameters, such as the cooling water temperature, the transmission gear, the driving speed, the air temperature and the accelerator pedal position is in many Cases desirable to increase or decrease the closing time, whereby an increase in the closing time, especially during the start-up phase, for improvement the performance data may be desirable, while a reduction in the closing time, is used in particular when a particularly strong reduction in the in the power loss occurring in the control circuit is to be achieved, for example if the engine or the internal combustion engine is idling when the vehicle is stationary works so that the cooling of strongly heating elements of the ignition system not due to the airstream.

Even with a strong acceleration of the internal combustion engine is one temporary sudden increase in the closing angle is desirable. To this Purpose can be connected to the circuit point 76 of the circuit according to FIG Voltage are applied by one during normal operation at this node the applied setpoint voltage deviates.

A voltage that indicates that the internal combustion engine is accelerating rapidly can be activated by pressing a switch when the vehicle is deeply depressed. or accelerator pedal can be obtained.

In addition or instead of this, this can occur during an acceleration process Voltage deviating from the setpoint voltage also from the impulses of an accelerator pedal sensor derived, as it is used in connection with injection pumps. In In this case, it is advantageous if the node 76 is an RC filter with a Resistor 78 and a capacitor 80 is connected upstream, as shown in the partial circuit diagram according to Fig. 4 shows.

In this circuit variant, the setpoint voltage then lags behind as before via a connection 82 at the switching point 76, while the accelerator pedal signal in the form of a direct voltage or a pulse train to a second connection 84 is fed to the input side of the RC filter and from its output to the node 76 arrives.

In principle, there is also the option of using an operating parameter corresponding voltage to superimpose the output signal of the encoder 10, as this the schematic partial circuit diagrams 5 and 6 show.

In detail, Fig. 5 shows a circuit variant in which in series to the coil 12 between battery voltage UB and reference potential two resistors 86.88, the common connection point of which is on the one hand with the circuit point 14 and on the other hand is connected to the emitter of a pre-transistor 90, whose Collector is at reference potential. The base of the pre-transistor 90 is at the tap a voltage divider made up of two resistors 92,94 in series to form a switch 96 lie between battery voltage UB and reference potential. If now the switch 96 as a function of an operating parameter, for example during an acceleration process, is closed by depressing the accelerator pedal, then the pre-transistor 90 is conductively controlled and thus changes the DC bias voltage at the circuit point 14, which corresponds to a change in the switching threshold of the first operational amplifier 18 results.

The circuit variant according to the partial circuit diagram in FIG. 6 corresponds largely the circuit variant according to FIG. 5, but differs therefrom in that there is also a diode 98 in the base connection of pre-transistor 90, whose cathode faces the base of the (pnp) pre-transistor 90 and via a Resistor 100 is at reference potential. In addition, the circuit is in accordance with Fig. 6, the resistor 88 divided into two partial resistors 88a and 88b, with their common connection point of the node 14 is connected.

The circuit according to FIG. 6 works as follows: if the switch 96 closes, then a current flows through the series circuit 92,94,96, which changes the base bias for transistor 90 since it is now parallel to the series connection of the resistor 100 and the diode 98, which is a temperature compensation the temperature behavior of the base-emitter path of the transistor 90 is used, which Series connection of the resistor 94 and the switch 96 is provided. The change the base bias or base current for transistor 90 has a corresponding one Change in the emitter current of this transistor, so that ultimately a corresponding bias change for the circuit point 14 at the tap of the off the resistors 86,88 formed voltage divider is obtained. This change in bias but affects the switching thresholds of a device connected to node 14 Trigger circuit.

Claims (9)

Claims D ignition device for an internal combustion engine with one in series with a DC voltage source, in particular a battery, and to the primary winding of an ignition coil lying electrical interrupter, its relative Closing time as a function of the output signal of a threshold switch depending on the speed is changeable, which on the input side a periodic control signal of a, in particular inductive signal transmitter synchronized with the internal combustion engine can be supplied and whose switching threshold can be changed by a control voltage, characterized in that that the control voltage can be changed as a function of the period duration of the control signal is. 2. Ignition device according to claim 1, characterized in that for A frequency-voltage converter (28) is provided to generate the control voltage, which is connected on the input side to the signal transmitter (10). 3. Ignition device according to claim 2, characterized in that the Frequency-voltage converter with the signal generator (10) via an operational amplifier (34) is connected to one input (+) of which the signal transmitter is connected and at its second input (-) the direct voltage (UB) or one derived from it Voltage is present. 4. Ignition device according to one of claims 1 to 3, characterized in that that the threshold switch is designed as an operational amplifier (18), on its one input (-) of the signal generator (10) is connected and to its second input (+) the output of the frequency-to-voltage converter (28) is connected. 5. Ignition device according to claim 2 and 3, characterized in that that the frequency-voltage converter (28) from the output of the operational amplifier (34) a square pulse train with the frequency of the signal generator signal can be supplied and that the frequency-voltage converter is designed as an integrator at its output (52) a voltage obtained by integrating the rectangular pulse sequence can be tapped is. 6. Ignition device according to claim 5, characterized in that the The frequency-voltage converter (28) has a storage capacitor (54) on the output side, on which one of the frequency of the square pulse train fed to it on the input side corresponding voltage can be stored. 7. Ignition device according to one of claims 1 to 6, characterized in that that in series with the breaker (78) a measuring resistor (60) is provided is that a sample and hold circuit (62) is provided, which via a first input (82) derived from the blocking signals for the interrupter (78) Gate switching pulses can be supplied and which has a second input (80), which is connected to the interrupter-side end of the measuring resistor (60) in such a way that that the current through the primary winding (76) of the ignition coil when locking the Interrupter (78) proportional voltage across the measuring resistor (60) when it occurs a gate pulse on one with an output of the sample and hold circuit (62) connected storage capacitor (64) can be stored that a control amplifier (66) is provided, one input (+) of which the voltage across the capacitor (64) can be fed and its second input (-) can be fed with a reference variable and that the output of the control amplifier (66) with an input of the threshold switch (18) is connected to influence the switching threshold of the same. 8. Ignition device according to claim 7, characterized in that the the reference variable fed to the second input (-) of the control amplifier (66) as a function of of an operating parameter of the internal combustion engine or one equipped with it Motor vehicle can be influenced. 9. Ignition device according to one of claims 1 to 5, characterized in that that the periodic control signal at an input of the threshold switch a as a function of an operating parameter of the internal combustion engine or the associated with it Equipped motor vehicle variable DC bias voltage can be superimposed (Fig. 5 and 6).